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# include "cmPrefix.h"
# include "cmGlobal.h"
# include "cmRpt.h"
# include "cmErr.h"
# include "cmCtx.h"
# include "cmMem.h"
# include "cmMallocDebug.h"
# include "cmLinkedHeap.h"
# include "cmSymTbl.h"
# include "cmFloatTypes.h"
# include "cmComplexTypes.h"
# include "cmFileSys.h"
# include "cmProcObj.h"
# include "cmProcTemplate.h"
# include "cmAudioFile.h"
# include "cmMath.h"
# include "cmProc.h"
# include "cmVectOps.h"
# include "cmKeyboard.h"
# include "cmGnuPlot.h"
# include <time.h> // time()
//------------------------------------------------------------------------------------------------------------
void cmFloatPointExceptHandler ( int signo , siginfo_t * info , void * context )
{
char * cp = " <Type Unknown> " ;
switch ( info - > si_code )
{
case FPE_INTDIV : cp = " integer divide by zero " ; break ;
case FPE_INTOVF : cp = " integer overflow " ; break ;
case FPE_FLTDIV : cp = " divide by zero " ; break ;
case FPE_FLTUND : cp = " underflow " ; break ;
case FPE_FLTRES : cp = " inexact result " ; break ;
case FPE_FLTINV : cp = " invalid operation " ; break ;
case FPE_FLTSUB : cp = " subscript range error " ; break ;
}
fprintf ( stderr , " Floating point exception: Type: %s \n " , cp ) ;
exit ( 1 ) ;
}
// set 'orgSaPtr' to NULL to discard the current signal action state
void cmSetupFloatPointExceptHandler ( struct sigaction * orgSaPtr )
{
struct sigaction sa ;
sa . sa_handler = SIG_DFL ;
sa . sa_flags = SA_SIGINFO ;
sa . sa_sigaction = cmFloatPointExceptHandler ;
sigemptyset ( & sa . sa_mask ) ;
// set all FP except flags excetp: FE_INEXACT
# ifdef OS_OSX
// we don't yet support FP exceptions on OSX
// for an example of how to make this work with the linux interface as below
// see: http://www-personal.umich.edu/~williams/archive/computation/fe-handling-example.c
assert ( 0 ) ;
# else
// int flags = FE_DIVBYZERO | FE_UNDERFLOW | FE_OVERFLOW | FE_INVALID;
// feenableexcept(flags);
assert ( 0 ) ;
# endif
sigaction ( SIGFPE , & sa , orgSaPtr ) ;
}
//------------------------------------------------------------------------------------------------------------
cmAudioFileRd * cmAudioFileRdAlloc ( cmCtx * c , cmAudioFileRd * p , unsigned procSmpCnt , const cmChar_t * fn , unsigned chIdx , unsigned begFrmIdx , unsigned endFrmIdx )
{
cmAudioFileRd * op = cmObjAlloc ( cmAudioFileRd , c , p ) ;
if ( fn ! = NULL )
if ( cmAudioFileRdOpen ( op , procSmpCnt , fn , chIdx , begFrmIdx , endFrmIdx ) ! = cmOkRC )
cmAudioFileRdFree ( & op ) ;
return op ;
}
cmRC_t cmAudioFileRdFree ( cmAudioFileRd * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmAudioFileRd * p = * pp ;
if ( ( rc = cmAudioFileRdClose ( p ) ) = = cmOkRC )
{
cmMemPtrFree ( & p - > outV ) ;
cmMemPtrFree ( & p - > fn ) ;
cmObjFree ( pp ) ;
}
}
return rc ;
}
cmRC_t cmAudioFileRdOpen ( cmAudioFileRd * p , unsigned procSmpCnt , const cmChar_t * fn , unsigned chIdx , unsigned begFrmIdx , unsigned endFrmIdx )
{
cmRC_t rc ;
cmRC_t afRC ;
if ( ( rc = cmAudioFileRdClose ( p ) ) ! = cmOkRC )
return rc ;
p - > h = cmAudioFileNewOpen ( fn , & p - > info , & afRC , p - > obj . err . rpt ) ;
if ( afRC ! = kOkAfRC )
return cmCtxRtCondition ( & p - > obj , afRC , " Unable to open the audio file:'%s' " , fn ) ;
p - > chIdx = chIdx ;
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p - > outN = endFrmIdx = = cmInvalidIdx ? p - > info . frameCnt : procSmpCnt ;
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p - > outV = cmMemResizeZ ( cmSample_t , p - > outV , p - > outN ) ;
p - > fn = cmMemResizeZ ( cmChar_t , p - > fn , strlen ( fn ) + 1 ) ;
strcpy ( p - > fn , fn ) ;
//p->mfp = cmCtxAllocDebugFile( p->obj.ctx,"audioFile");
p - > lastReadFrmCnt = 0 ;
p - > eofFl = false ;
p - > begFrmIdx = begFrmIdx ;
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p - > endFrmIdx = endFrmIdx = = 0 ? p - > info . frameCnt : endFrmIdx ;
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p - > curFrmIdx = p - > begFrmIdx ;
if ( p - > begFrmIdx > 0 )
rc = cmAudioFileRdSeek ( p , p - > begFrmIdx ) ;
return rc ;
}
cmRC_t cmAudioFileRdClose ( cmAudioFileRd * p )
{
cmRC_t rc = cmOkRC ;
cmRC_t afRC ;
if ( p = = NULL )
return cmOkRC ;
//cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
if ( cmAudioFileIsOpen ( p - > h ) = = false )
return cmOkRC ;
if ( ( afRC = cmAudioFileDelete ( & p - > h ) ) ! = cmOkRC )
rc = cmCtxRtCondition ( & p - > obj , afRC , " An attempt to close the audio file'%s' failed. " , p - > fn ) ;
return rc ;
}
cmRC_t cmAudioFileRdRead ( cmAudioFileRd * p )
{
cmRC_t rc = cmOkRC ;
cmRC_t afRC ;
if ( p - > eofFl | | ( ( p - > eofFl = cmAudioFileIsEOF ( p - > h ) ) = = true ) )
return cmEofRC ;
unsigned n = p - > endFrmIdx = = cmInvalidIdx ? p - > outN : cmMin ( p - > outN , p - > endFrmIdx - p - > curFrmIdx ) ;
if ( ( afRC = cmAudioFileReadSample ( p - > h , n , p - > chIdx , 1 , & p - > outV , & p - > lastReadFrmCnt ) ) ! = kOkAfRC )
rc = cmCtxRtCondition ( & p - > obj , afRC , " Audio file read failed on:'%s'. " , p - > fn ) ;
p - > curFrmIdx + = p - > lastReadFrmCnt ;
if ( n < p - > outN )
{
cmVOS_Zero ( p - > outV + p - > lastReadFrmCnt , p - > outN - p - > lastReadFrmCnt ) ;
p - > eofFl = true ;
}
if ( p - > mfp ! = NULL )
cmMtxFileSmpExec ( p - > mfp , p - > outV , p - > outN ) ;
return rc ;
}
cmRC_t cmAudioFileRdSeek ( cmAudioFileRd * p , unsigned frmIdx )
{
cmRC_t rc = cmOkRC ;
cmRC_t afRC ;
if ( ( afRC = cmAudioFileSeek ( p - > h , frmIdx ) ) ! = kOkAfRC )
rc = cmCtxRtCondition ( & p - > obj , afRC , " Audio file read failed on:'%s'. " , p - > fn ) ;
return rc ;
}
cmRC_t cmAudioFileRdMinMaxMean ( cmAudioFileRd * p , unsigned chIdx , cmSample_t * minPtr , cmSample_t * maxPtr , cmSample_t * meanPtr )
{
cmRC_t rc = cmOkRC ;
cmRC_t afRC ;
if ( ( afRC = cmAudioFileMinMaxMean ( p - > h , chIdx , minPtr , maxPtr , meanPtr ) ) ! = kOkAfRC )
rc = cmCtxRtCondition ( & p - > obj , afRC , " Audio file min, max, and mean calculation failed on '%s' " , p - > fn ) ;
return rc ;
}
//------------------------------------------------------------------------------------------------------------
cmShiftBuf * cmShiftBufAlloc ( cmCtx * c , cmShiftBuf * p , unsigned procSmpCnt , unsigned wndSmpCnt , unsigned hopSmpCnt )
{
cmShiftBuf * op = cmObjAlloc ( cmShiftBuf , c , p ) ;
if ( procSmpCnt > 0 & & wndSmpCnt > 0 & & hopSmpCnt > 0 )
if ( cmShiftBufInit ( op , procSmpCnt , wndSmpCnt , hopSmpCnt ) ! = cmOkRC )
cmShiftBufFree ( & op ) ;
return op ;
}
cmRC_t cmShiftBufFree ( cmShiftBuf * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp ! = NULL & & * pp ! = NULL )
{
if ( ( rc = cmShiftBufFinal ( * pp ) ) = = cmOkRC )
{
cmMemPtrFree ( & ( * pp ) - > bufV ) ;
cmObjFree ( pp ) ;
}
}
return rc ;
}
cmRC_t cmShiftBufInit ( cmShiftBuf * p , unsigned procSmpCnt , unsigned wndSmpCnt , unsigned hopSmpCnt )
{
cmRC_t rc ;
if ( hopSmpCnt > wndSmpCnt )
return cmCtxRtAssertFailed ( & p - > obj , cmArgAssertRC , " The window sample count (%i) must be greater than or equal to the hop sample count ( % i ) . " , wndSmpCnt, hopSmpCnt ) ;
if ( ( rc = cmShiftBufFinal ( p ) ) ! = cmOkRC )
return rc ;
// The worst case storage requirement is where there are wndSmpCnt-1 samples in outV[] and procSmpCnt new samples arrive.
p - > bufSmpCnt = wndSmpCnt + procSmpCnt ;
p - > bufV = cmMemResizeZ ( cmSample_t , p - > outV , p - > bufSmpCnt ) ;
p - > outV = p - > bufV ;
p - > outN = wndSmpCnt ;
p - > wndSmpCnt = wndSmpCnt ;
p - > procSmpCnt = procSmpCnt ;
p - > hopSmpCnt = hopSmpCnt ;
p - > inPtr = p - > outV ;
p - > fl = false ;
return cmOkRC ;
}
cmRC_t cmShiftBufFinal ( cmShiftBuf * p )
{
return cmOkRC ;
}
// This function should be called in a loop until it returns false.
// Note that 'sp' and 'sn' are ignored except p->fl == false.
bool cmShiftBufExec ( cmShiftBuf * p , const cmSample_t * sp , unsigned sn )
{
assert ( sn < = p - > procSmpCnt ) ;
// The active samples are in outV[wndSmpCnt]
// Stored samples are between outV + wndSmpCnt and inPtr.
// if the previous call to this function returned true then the buffer must be
// shifted by hopSmpCnt samples - AND sp[] is ignored.
if ( p - > fl )
{
// shift the output buffer to the left to remove expired samples
p - > outV + = p - > hopSmpCnt ;
// if there are not wndSmpCnt samples left in the buffer
if ( p - > inPtr - p - > outV < p - > wndSmpCnt )
{
// then copy the remaining active samples (between outV and inPtr)
// to the base of the physicalbuffer
unsigned n = p - > inPtr - p - > outV ;
memmove ( p - > bufV , p - > outV , n * sizeof ( cmSample_t ) ) ;
p - > inPtr = p - > bufV + n ; // update the input and output positions
p - > outV = p - > bufV ;
}
}
else
{
// if the previous call to this function returned false then sp[sn] should not be ignored
assert ( p - > inPtr + sn < = p - > outV + p - > bufSmpCnt ) ;
// copy the incoming samples into the buffer
cmVOS_Copy ( p - > inPtr , sn , sp ) ;
p - > inPtr + = sn ;
}
// if there are at least wndSmpCnt available samples in outV[]
p - > fl = p - > inPtr - p - > outV > = p - > wndSmpCnt ;
return p - > fl ;
}
void cmShiftBufTest ( cmCtx * c )
{
unsigned smpCnt = 48 ;
unsigned procSmpCnt = 5 ;
unsigned hopSmpCnt = 6 ;
unsigned wndSmpCnt = 7 ;
unsigned i ;
cmShiftBuf * b = cmShiftBufAlloc ( c , NULL , procSmpCnt , wndSmpCnt , hopSmpCnt ) ;
cmSample_t x [ smpCnt ] ;
cmVOS_Seq ( x , smpCnt , 1 , 1 ) ;
//cmVOS_Print( rptFuncPtr, 1, smpCnt, x );
for ( i = 0 ; i < smpCnt ; i + = procSmpCnt )
{
while ( cmShiftBufExec ( b , x + i , procSmpCnt ) )
{
cmVOS_Print ( c - > obj . err . rpt , 1 , wndSmpCnt , b - > outV ) ;
}
}
cmShiftBufFree ( & b ) ;
}
/*
bool cmShiftBufExec ( cmShiftBuf * p , const cmSample_t * sp , unsigned sn )
{
bool retFl = false ;
if ( sn > p - > procSmpCnt )
{
cmCtxRtAssertFailed ( p - > obj . ctx , cmArgAssertRC , " The input sample count (%i) must be less than or equal to the proc sample count (%i). " , sn , p - > procSmpCnt ) ;
return false ;
}
assert ( sn < = p - > procSmpCnt ) ;
cmSample_t * dbp = p - > outV ;
cmSample_t * dep = p - > outV + ( p - > outN - sn ) ;
cmSample_t * sbp = p - > outV + sn ;
// shift the last bufCnt-shiftCnt samples over the first shiftCnt samples
while ( dbp < dep )
* dbp + + = * sbp + + ;
// copy in the new samples
dbp = dep ;
dep = dbp + sn ;
while ( dbp < dep )
* dbp + + = * sp + + ;
// if any space remains at the end of the buffer then zero it
dep = p - > outV + p - > outN ;
while ( dbp < dep )
* dbp + + = 0 ;
if ( p - > firstPtr > p - > outV )
p - > firstPtr = cmMax ( p - > outV , p - > firstPtr - p - > procSmpCnt ) ;
p - > curHopSmpCnt + = sn ;
if ( p - > curHopSmpCnt > = p - > hopSmpCnt )
{
p - > curHopSmpCnt - = p - > hopSmpCnt ;
retFl = true ;
}
if ( p - > mfp ! = NULL )
cmMtxFileSmpExec ( p - > mfp , p - > outV , p - > outN ) ;
return retFl ;
}
*/
//------------------------------------------------------------------------------------------------------------
cmWndFunc * cmWndFuncAlloc ( cmCtx * c , cmWndFunc * p , unsigned wndId , unsigned wndSmpCnt , double kaiserSideLobeRejectDb )
{
cmWndFunc * op = cmObjAlloc ( cmWndFunc , c , p ) ;
if ( wndId ! = kInvalidWndId )
if ( cmWndFuncInit ( op , wndId , wndSmpCnt , kaiserSideLobeRejectDb ) ! = cmOkRC )
cmWndFuncFree ( & op ) ;
return op ;
}
cmRC_t cmWndFuncFree ( cmWndFunc * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmWndFunc * p = * pp ;
if ( ( rc = cmWndFuncFinal ( p ) ) = = cmOkRC )
{
cmMemPtrFree ( & p - > wndV ) ;
cmMemPtrFree ( & p - > outV ) ;
cmObjFree ( pp ) ;
}
}
return rc ;
}
cmRC_t cmWndFuncInit ( cmWndFunc * p , unsigned wndId , unsigned wndSmpCnt , double kslRejectDb )
{
cmRC_t rc ;
if ( wndId = = ( p - > wndId | p - > flags ) & & wndSmpCnt = = p - > outN & & kslRejectDb = = p - > kslRejectDb )
return cmOkRC ;
if ( ( rc = cmWndFuncFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > wndV = cmMemResize ( cmSample_t , p - > wndV , wndSmpCnt ) ;
p - > outV = cmMemResize ( cmSample_t , p - > outV , wndSmpCnt ) ;
p - > outN = wndSmpCnt ;
p - > wndId = wndId ;
p - > kslRejectDb = kslRejectDb ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"wndFunc");
p - > flags = wndId & ( ~ kWndIdMask ) ;
switch ( wndId & kWndIdMask )
{
case kHannWndId : cmVOS_Hann ( p - > wndV , p - > outN ) ; break ;
case kHannMatlabWndId : cmVOS_HannMatlab ( p - > wndV , p - > outN ) ; break ;
case kHammingWndId : cmVOS_Hamming ( p - > wndV , p - > outN ) ; break ;
case kTriangleWndId : cmVOS_Triangle ( p - > wndV , p - > outN ) ; break ;
case kUnityWndId : cmVOS_Fill ( p - > wndV , p - > outN , 1.0 ) ; break ;
case kKaiserWndId :
{
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double beta ;
if ( cmIsFlag ( wndId , kSlRejIsBetaWndFl ) )
beta = kslRejectDb ;
else
beta = cmVOS_KaiserBetaFromSidelobeReject ( fabs ( kslRejectDb ) ) ;
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cmVOS_Kaiser ( p - > wndV , p - > outN , beta ) ;
}
break ;
case kInvalidWndId : break ;
default :
{ assert ( 0 ) ; }
}
cmSample_t den = 0 ;
cmSample_t num = 1 ;
if ( cmIsFlag ( p - > flags , kNormBySumWndFl ) )
{
den = cmVOS_Sum ( p - > wndV , p - > outN ) ;
num = wndSmpCnt ;
}
if ( cmIsFlag ( p - > flags , kNormByLengthWndFl ) )
den + = wndSmpCnt ;
if ( den > 0 )
{
cmVOS_MultVS ( p - > wndV , p - > outN , num ) ;
cmVOS_DivVS ( p - > wndV , p - > outN , den ) ;
}
return cmOkRC ;
}
cmRC_t cmWndFuncFinal ( cmWndFunc * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmWndFuncExec ( cmWndFunc * p , const cmSample_t * sp , unsigned sn )
{
if ( sn > p - > outN )
return cmCtxRtAssertFailed ( & p - > obj , cmArgAssertRC , " The length of the input vector (%i) is greater thean the length of the window function ( % i ) . " , sn, p->outN ) ;
if ( p - > wndId ! = kInvalidWndId )
cmVOS_MultVVV ( p - > outV , sn , sp , p - > wndV ) ;
if ( p - > mfp ! = NULL )
cmMtxFileSmpExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
void cmWndFuncTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
unsigned wndCnt = 5 ;
double kaiserSideLobeRejectDb = 30 ;
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmWndFunc * p = cmWndFuncAlloc ( & c , NULL , kHannWndId , wndCnt , 0 ) ;
cmVOS_Print ( rpt , 1 , wndCnt , p - > wndV ) ;
cmWndFuncInit ( p , kHammingWndId , wndCnt , 0 ) ;
cmVOS_Print ( rpt , 1 , wndCnt , p - > wndV ) ;
cmWndFuncInit ( p , kTriangleWndId , wndCnt , 0 ) ;
cmVOS_Print ( rpt , 1 , wndCnt , p - > wndV ) ;
cmWndFuncInit ( p , kKaiserWndId , wndCnt , kaiserSideLobeRejectDb ) ;
cmVOS_Print ( rpt , 1 , wndCnt , p - > wndV ) ;
cmSample_t wV [ wndCnt ] ;
cmVOS_HannMatlab ( wV , wndCnt ) ;
cmVOS_Print ( rpt , 1 , wndCnt , wV ) ;
cmWndFuncFree ( & p ) ;
}
//------------------------------------------------------------------------------------------------------------
cmSpecDelay * cmSpecDelayAlloc ( cmCtx * c , cmSpecDelay * ap , unsigned maxDelayCnt , unsigned binCnt )
{
cmSpecDelay * p = cmObjAlloc ( cmSpecDelay , c , ap ) ;
if ( maxDelayCnt > 0 & & binCnt > 0 )
if ( cmSpecDelayInit ( p , maxDelayCnt , binCnt ) ! = cmOkRC )
cmSpecDelayFree ( & p ) ;
return p ;
}
cmRC_t cmSpecDelayFree ( cmSpecDelay * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmSpecDelay * p = * pp ;
if ( ( rc = cmSpecDelayFinal ( p ) ) = = cmOkRC )
{
cmMemPtrFree ( & p - > bufPtr ) ;
cmObjFree ( pp ) ;
}
}
return rc ;
}
cmRC_t cmSpecDelayInit ( cmSpecDelay * p , unsigned maxDelayCnt , unsigned binCnt )
{
cmRC_t rc ;
if ( ( rc = cmSpecDelayFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > bufPtr = cmMemResizeZ ( cmSample_t , p - > bufPtr , binCnt * maxDelayCnt ) ;
p - > maxDelayCnt = maxDelayCnt ;
p - > outN = binCnt ;
p - > inIdx = 0 ;
return cmOkRC ;
}
cmRC_t cmSpecDelayFinal ( cmSpecDelay * p )
{ return cmOkRC ; }
cmRC_t cmSpecDelayExec ( cmSpecDelay * p , const cmSample_t * sp , unsigned sn )
{
cmSample_t * dp = p - > bufPtr + ( p - > inIdx * p - > outN ) ;
cmVOS_Copy ( dp , cmMin ( sn , p - > outN ) , sp ) ;
p - > inIdx = ( p - > inIdx + 1 ) % p - > maxDelayCnt ;
return cmOkRC ;
}
const cmSample_t * cmSpecDelayOutPtr ( cmSpecDelay * p , unsigned delayCnt )
{
assert ( delayCnt < p - > maxDelayCnt ) ;
int i = p - > inIdx - delayCnt ;
if ( i < 0 )
i = p - > maxDelayCnt + i ;
return p - > bufPtr + ( i * p - > outN ) ;
}
//------------------------------------------------------------------------------------------------------------
cmFilter * cmFilterAlloc ( cmCtx * c , cmFilter * ap , const cmReal_t * b , unsigned bn , const cmReal_t * a , unsigned an , unsigned procSmpCnt , const cmReal_t * d )
{
cmRC_t rc ;
cmFilter * p = cmObjAlloc ( cmFilter , c , ap ) ;
if ( ( bn > 0 | | an > 0 ) & & procSmpCnt > 0 )
if ( ( rc = cmFilterInit ( p , b , bn , a , an , procSmpCnt , d ) ) ! = cmOkRC )
cmFilterFree ( & p ) ;
return p ;
}
cmFilter * cmFilterAllocEllip ( cmCtx * c , cmFilter * ap , cmReal_t srate , cmReal_t passHz , cmReal_t stopHz , cmReal_t passDb , cmReal_t stopDb , unsigned procSmpCnt , const cmReal_t * d )
{
cmRC_t rc ;
cmFilter * p = cmObjAlloc ( cmFilter , c , ap ) ;
if ( srate > 0 & & passHz > 0 & & procSmpCnt > 0 )
if ( ( rc = cmFilterInitEllip ( p , srate , passHz , stopHz , passDb , stopDb , procSmpCnt , d ) ) ! = cmOkRC )
cmFilterFree ( & p ) ;
return p ;
}
cmRC_t cmFilterFree ( cmFilter * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmFilter * p = * pp ;
if ( ( rc = cmFilterFinal ( p ) ) = = cmOkRC )
{
cmMemPtrFree ( & p - > a ) ;
cmMemPtrFree ( & p - > b ) ;
cmMemPtrFree ( & p - > d ) ;
cmMemPtrFree ( & p - > outSmpV ) ;
cmObjFree ( pp ) ;
}
}
return rc ;
}
cmRC_t cmFilterInit ( cmFilter * p , const cmReal_t * b , unsigned bn , const cmReal_t * a , unsigned an , unsigned procSmpCnt , const cmReal_t * d )
{
assert ( bn > = 1 ) ;
assert ( an > = 1 & & a [ 0 ] ! = 0 ) ;
cmRC_t rc ;
if ( ( rc = cmFilterFinal ( p ) ) ! = cmOkRC )
return rc ;
int cn = cmMax ( an , bn ) - 1 ;
// The output vector may be used as either cmReal_t or cmSample_t.
// Find the larger of the two possible types.
if ( sizeof ( cmReal_t ) > sizeof ( cmSample_t ) )
{
p - > outRealV = cmMemResizeZ ( cmReal_t , p - > outRealV , procSmpCnt ) ;
p - > outSmpV = ( cmSample_t * ) p - > outRealV ;
}
else
{
p - > outSmpV = cmMemResizeZ ( cmSample_t , p - > outSmpV , procSmpCnt ) ;
p - > outRealV = ( cmReal_t * ) p - > outRealV ;
}
p - > a = cmMemResizeZ ( cmReal_t , p - > a , cn ) ;
p - > b = cmMemResizeZ ( cmReal_t , p - > b , cn ) ;
p - > d = cmMemResizeZ ( cmReal_t , p - > d , cn + 1 ) ;
//p->outV = cmMemResizeZ( cmSample_t, p->outV, procSmpCnt );
p - > outN = procSmpCnt ;
p - > an = an ;
p - > bn = bn ;
p - > cn = cn ;
p - > di = 0 ;
p - > b0 = b [ 0 ] / a [ 0 ] ;
int i ;
for ( i = 0 ; i < an - 1 ; + + i )
p - > a [ i ] = a [ i + 1 ] / a [ 0 ] ;
for ( i = 0 ; i < bn - 1 ; + + i )
p - > b [ i ] = b [ i + 1 ] / a [ 0 ] ;
if ( d ! = NULL )
cmVOR_Copy ( p - > d , cn , d ) ;
return cmOkRC ;
}
// initialize an elliptic lowpass filter with the given characteristics
// ref: Parks & Burrus, Digital Filter Design, sec. 7.2.7 - 7.2.8
cmRC_t cmFilterInitEllip ( cmFilter * p , cmReal_t srate , cmReal_t passHz , cmReal_t stopHz , cmReal_t passDb , cmReal_t stopDb , unsigned procSmpCnt , const cmReal_t * d )
{
assert ( srate > 0 ) ;
assert ( passHz > 0 & & stopHz > passHz & & srate / 2 > stopHz ) ;
cmReal_t Wp , Ws , ep , v0 ,
k , kc , k1 , k1c ,
K , Kc , K1 , K1c ,
sn , cn , dn ,
sm , cm , dm ,
zr , zi , pr , pi ;
unsigned N , L , j ;
// prewarp Wp and Ws, calculate k
Wp = 2 * srate * tan ( M_PI * passHz / srate ) ;
Ws = 2 * srate * tan ( M_PI * stopHz / srate ) ;
k = Wp / Ws ;
// calculate ep and k1 from passDb and stopDb
ep = sqrt ( pow ( 10 , passDb / 10 ) - 1 ) ;
k1 = ep / sqrt ( pow ( 10 , stopDb / 10 ) - 1 ) ;
// calculate complimentary moduli
kc = sqrt ( 1 - k * k ) ;
k1c = sqrt ( 1 - k1 * k1 ) ;
// calculate complete elliptic integrals
K = cmEllipK ( kc ) ;
Kc = cmEllipK ( k ) ;
K1 = cmEllipK ( k1c ) ;
K1c = cmEllipK ( k1 ) ;
// calculate minimum integer filter order N
N = ceil ( K * K1c / Kc / K1 ) ;
// recalculate k and kc from chosen N
// Ws is minimized while other specs held constant
k = cmEllipDeg ( K1c / K1 / N ) ;
kc = sqrt ( 1 - k * k ) ;
K = cmEllipK ( kc ) ;
Kc = cmEllipK ( k ) ;
Ws = Wp / k ;
// initialize temporary coefficient arrays
cmReal_t b [ N + 1 ] , a [ N + 1 ] ;
a [ 0 ] = b [ 0 ] = 1 ;
memset ( b + 1 , 0 , N * sizeof ( cmReal_t ) ) ;
memset ( a + 1 , 0 , N * sizeof ( cmReal_t ) ) ;
// intermediate value needed for determining poles
v0 = K / K1 / N * cmEllipArcSc ( 1 / ep , k1 ) ;
cmEllipJ ( v0 , k , & sm , & cm , & dm ) ;
for ( L = 1 - N % 2 ; L < N ; L + = 2 )
{
// find the next pole and zero on s-plane
cmEllipJ ( K * L / N , kc , & sn , & cn , & dn ) ;
zr = 0 ;
zi = L ? Ws / sn : 1E25 ;
pr = - Wp * sm * cm * cn * dn / ( 1 - pow ( dn * sm , 2 ) ) ;
pi = Wp * dm * sn / ( 1 - pow ( dn * sm , 2 ) ) ;
// convert pole and zero to z-plane using bilinear transform
cmBlt ( 1 , srate , & zr , & zi ) ;
cmBlt ( 1 , srate , & pr , & pi ) ;
if ( L = = 0 )
{
// first order section
b [ 1 ] = - zr ;
a [ 1 ] = - pr ;
}
else
{
// replace complex root and its conjugate with 2nd order section
zi = zr * zr + zi * zi ;
zr * = - 2 ;
pi = pr * pr + pi * pi ;
pr * = - 2 ;
// combine with previous sections to obtain filter coefficients
for ( j = L + 1 ; j > = 2 ; j - - )
{
b [ j ] = b [ j ] + zr * b [ j - 1 ] + zi * b [ j - 2 ] ;
a [ j ] = a [ j ] + pr * a [ j - 1 ] + pi * a [ j - 2 ] ;
}
b [ 1 ] + = zr ;
a [ 1 ] + = pr ;
}
}
// scale b coefficients s.t. DC gain is 0 dB
cmReal_t sumB = 0 , sumA = 0 ;
for ( j = 0 ; j < N + 1 ; j + + )
{
sumB + = b [ j ] ;
sumA + = a [ j ] ;
}
sumA / = sumB ;
for ( j = 0 ; j < N + 1 ; j + + )
b [ j ] * = sumA ;
return cmFilterInit ( p , b , N + 1 , a , N + 1 , procSmpCnt , d ) ;
}
cmRC_t cmFilterFinal ( cmFilter * p )
{ return cmOkRC ; }
cmRC_t cmFilterExecS ( cmFilter * p , const cmSample_t * x , unsigned xn , cmSample_t * yy , unsigned yn )
{
cmSample_t * y ;
if ( yy = = NULL | | yn = = 0 )
{
y = p - > outSmpV ;
yn = p - > outN ;
}
else
{
y = yy ;
}
cmVOS_Filter ( y , yn , x , xn , p - > b0 , p - > b , p - > a , p - > d , p - > cn ) ;
return cmOkRC ;
/*
int i , j ;
cmSample_t y0 = 0 ;
cmSample_t * y ;
unsigned n ;
if ( yy = = NULL | | yn = = 0 )
{
n = cmMin ( p - > outN , xn ) ;
y = p - > outSmpV ;
yn = p - > outN ;
}
else
{
n = cmMin ( yn , xn ) ;
y = yy ;
}
// This is a direct form II algorithm based on the MATLAB implmentation
// http://www.mathworks.com/access/helpdesk/help/techdoc/ref/filter.html#f83-1015962
for ( i = 0 ; i < n ; + + i )
{
//cmSample_t x0 = x[i];
y [ i ] = ( x [ i ] * p - > b0 ) + p - > d [ 0 ] ;
y0 = y [ i ] ;
for ( j = 0 ; j < p - > cn ; + + j )
p - > d [ j ] = ( p - > b [ j ] * x [ i ] ) - ( p - > a [ j ] * y0 ) + p - > d [ j + 1 ] ;
}
// if fewer input samples than output samples - zero the end of the output buffer
if ( yn > xn )
cmVOS_Fill ( y + i , yn - i , 0 ) ;
return cmOkRC ;
*/
}
cmRC_t cmFilterExecR ( cmFilter * p , const cmReal_t * x , unsigned xn , cmReal_t * yy , unsigned yn )
{
cmReal_t * y ;
if ( yy = = NULL | | yn = = 0 )
{
y = p - > outRealV ;
yn = p - > outN ;
}
else
{
//n = cmMin(yn,xn);
y = yy ;
}
cmVOR_Filter ( y , yn , x , xn , p - > b0 , p - > b , p - > a , p - > d , p - > cn ) ;
return cmOkRC ;
}
cmRC_t cmFilterSignal ( cmCtx * c , const cmReal_t b [ ] , unsigned bn , const cmReal_t a [ ] , unsigned an , const cmSample_t * x , unsigned xn , cmSample_t * y , unsigned yn )
{
int procSmpCnt = cmMin ( 1024 , xn ) ;
cmFilter * p = cmFilterAlloc ( c , NULL , b , bn , a , an , procSmpCnt , NULL ) ;
int i , n ;
for ( i = 0 ; i < xn & & i < yn ; i + = n )
{
n = cmMin ( procSmpCnt , cmMin ( yn - i , xn - i ) ) ;
cmFilterExecS ( p , x + i , n , y + i , n ) ;
}
if ( i < yn )
cmVOS_Fill ( y + i , yn - i , 0 ) ;
cmFilterFree ( & p ) ;
return cmOkRC ;
}
cmRC_t cmFilterFilterS ( cmCtx * c , const cmReal_t bb [ ] , unsigned bn , const cmReal_t aa [ ] , unsigned an , const cmSample_t * x , unsigned xn , cmSample_t * y , unsigned yn )
{
cmFilter * f = cmFilterAlloc ( c , NULL , NULL , 0 , NULL , 0 , 0 , NULL ) ;
cmVOS_FilterFilter ( f , cmFilterExecS , bb , bn , aa , an , x , xn , y , yn ) ;
cmFilterFree ( & f ) ;
return cmOkRC ;
}
cmRC_t cmFilterFilterR ( cmCtx * c , const cmReal_t bb [ ] , unsigned bn , const cmReal_t aa [ ] , unsigned an , const cmReal_t * x , unsigned xn , cmReal_t * y , unsigned yn )
{
cmFilter * f = cmFilterAlloc ( c , NULL , NULL , 0 , NULL , 0 , 0 , NULL ) ;
cmVOR_FilterFilter ( f , cmFilterExecR , bb , bn , aa , an , x , xn , y , yn ) ;
cmFilterFree ( & f ) ;
return cmOkRC ;
}
void cmFilterTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmReal_t b [ ] = { 0.16 , 0.32 , 0.16 } ;
unsigned bn = sizeof ( b ) / sizeof ( cmReal_t ) ;
cmReal_t a [ ] = { 1 , - .5949 , .2348 } ;
unsigned an = sizeof ( a ) / sizeof ( cmReal_t ) ;
cmReal_t x [ ] = { 1 , 0 , 0 , 0 , 1 , 0 , 0 , 0 } ;
unsigned xn = sizeof ( x ) / sizeof ( cmReal_t ) ;
cmReal_t d [ ] = { .5 , - .25 } ;
// 0.1600 0.4152 0.3694 0.1223 0.1460 0.3781 0.3507 0.1198
// -0.0111 -0.0281
cmFilter * p = cmFilterAlloc ( & c , NULL , b , bn , a , an , xn , d ) ;
cmFilterExecR ( p , x , xn , NULL , 0 ) ;
cmVOR_Print ( rpt , 1 , xn , p - > outRealV ) ;
cmVOR_Print ( rpt , 1 , p - > cn , p - > d ) ;
cmFilterFree ( & p ) ;
cmObjFreeStatic ( cmCtxFree , cmCtx , c ) ;
/*
cmReal_t b [ ] = { 0.16 , 0.32 , 0.16 } ;
unsigned bn = sizeof ( b ) / sizeof ( cmReal_t ) ;
cmReal_t a [ ] = { 1 , - .5949 , .2348 } ;
unsigned an = sizeof ( a ) / sizeof ( cmReal_t ) ;
cmSample_t x [ ] = { 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 } ;
unsigned xn = sizeof ( x ) / sizeof ( cmSample_t ) ;
cmFilter * p = cmFilterAlloc ( & c , NULL , b , bn , a , an , xn ) ;
cmFilterExec ( & c , p , x , xn , NULL , 0 ) ;
cmVOS_Print ( vReportFunc , 1 , xn , p - > outV ) ;
cmVOR_Print ( vReportFunc , 1 , p - > cn , p - > d ) ;
cmFilterExec ( & c , p , x , xn , NULL , 0 ) ;
cmVOS_Print ( vReportFunc , 1 , xn , p - > outV ) ;
cmFilterFree ( & p ) ;
*/
}
void cmFilterFilterTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmReal_t b [ ] = { 0.36 , 0.32 , 0.36 } ;
unsigned bn = sizeof ( b ) / sizeof ( cmReal_t ) ;
cmReal_t a [ ] = { 1 , - .5949 , .2348 } ;
unsigned an = sizeof ( a ) / sizeof ( cmReal_t ) ;
cmReal_t x [ ] = { 1 , 0 , 1 , 0 , 1 , 0 , 1 , 0 , 1 , 0 , 1 , 0 , 1 , 0 , 1 , 0 } ;
unsigned xn = sizeof ( x ) / sizeof ( cmReal_t ) ;
unsigned yn = xn ;
cmReal_t y [ yn ] ;
memset ( y , 0 , sizeof ( y ) ) ;
cmFilterFilterR ( & c , b , bn , a , an , x , xn , y , yn ) ;
cmVOR_Print ( rpt , 1 , yn , y ) ;
cmObjFreeStatic ( cmCtxFree , cmCtx , c ) ;
}
//------------------------------------------------------------------------------------------------------------
cmComplexDetect * cmComplexDetectAlloc ( cmCtx * c , cmComplexDetect * p , unsigned binCnt )
{
cmComplexDetect * op = cmObjAlloc ( cmComplexDetect , c , p ) ;
cmSpecDelayAlloc ( c , & op - > phsDelay , 0 , 0 ) ;
cmSpecDelayAlloc ( c , & op - > magDelay , 0 , 0 ) ;
if ( binCnt > 0 )
if ( cmComplexDetectInit ( op , binCnt ) ! = cmOkRC & & p = = NULL )
cmComplexDetectFree ( & op ) ;
return op ;
}
cmRC_t cmComplexDetectFree ( cmComplexDetect * * pp )
{
cmRC_t rc ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmComplexDetect * p = * pp ;
if ( ( rc = cmComplexDetectFinal ( p ) ) = = cmOkRC )
{
cmSpecDelay * sdp ;
sdp = & p - > phsDelay ;
cmSpecDelayFree ( & sdp ) ;
sdp = & p - > magDelay ;
cmSpecDelayFree ( & sdp ) ;
cmObjFree ( pp ) ;
}
}
return cmOkRC ;
}
cmRC_t cmComplexDetectInit ( cmComplexDetect * p , unsigned binCnt )
{
cmRC_t rc ;
if ( ( rc = cmComplexDetectFinal ( p ) ) ! = cmOkRC )
return rc ;
cmSpecDelayInit ( & p - > phsDelay , 2 , binCnt ) ;
cmSpecDelayInit ( & p - > magDelay , 1 , binCnt ) ;
p - > binCnt = binCnt ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"complexDetect");
//p->cdfSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kCDF_FId, 1 );
return cmOkRC ;
}
cmRC_t cmComplexDetectFinal ( cmComplexDetect * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmComplexDetectExec ( cmComplexDetect * p , const cmSample_t * magV , const cmSample_t * phsV , unsigned binCnt )
{
p - > out = cmVOS_ComplexDetect ( magV , cmSpecDelayOutPtr ( & p - > magDelay , 0 ) , phsV , cmSpecDelayOutPtr ( & p - > phsDelay , 1 ) , cmSpecDelayOutPtr ( & p - > phsDelay , 0 ) , binCnt ) ;
p - > out / = 10000000 ;
cmSpecDelayExec ( & p - > magDelay , magV , binCnt ) ;
cmSpecDelayExec ( & p - > phsDelay , phsV , binCnt ) ;
//if( p->mfp != NULL )
// cmMtxFileSmpExec( p->mfp, &p->out, 1 );
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmSample_t _cmComplexOnsetMedian ( const cmSample_t * sp , unsigned sn , void * userPtr )
{ return cmVOS_Median ( sp , sn ) ; }
cmComplexOnset * cmComplexOnsetAlloc ( cmCtx * c , cmComplexOnset * p , unsigned procSmpCnt , double srate , unsigned medFiltWndSmpCnt , double threshold , unsigned frameCnt )
{
cmComplexOnset * op = cmObjAlloc ( cmComplexOnset , c , p ) ;
if ( procSmpCnt > 0 & & srate > 0 & & medFiltWndSmpCnt > 0 )
if ( cmComplexOnsetInit ( op , procSmpCnt , srate , medFiltWndSmpCnt , threshold , frameCnt ) ! = cmOkRC )
cmComplexOnsetFree ( & op ) ;
return op ;
}
cmRC_t cmComplexOnsetFree ( cmComplexOnset * * pp )
{
cmRC_t rc = cmOkRC ;
cmComplexOnset * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmComplexOnsetFinal ( * pp ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > df ) ;
cmMemPtrFree ( & p - > fdf ) ;
cmObjFree ( pp ) ;
return cmOkRC ;
}
cmRC_t cmComplexOnsetInit ( cmComplexOnset * p , unsigned procSmpCnt , double srate , unsigned medFiltWndSmpCnt , double threshold , unsigned frameCnt )
{
cmRC_t rc ;
if ( ( rc = cmComplexOnsetFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > frmCnt = frameCnt ;
p - > dfi = 0 ;
p - > df = cmMemResizeZ ( cmSample_t , p - > df , frameCnt ) ;
p - > fdf = cmMemResizeZ ( cmSample_t , p - > fdf , frameCnt ) ;
p - > onrate = 0 ;
p - > threshold = threshold ;
p - > medSmpCnt = medFiltWndSmpCnt ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"complexOnset");
return cmOkRC ;
}
cmRC_t cmComplexOnsetFinal ( cmComplexOnset * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmComplexOnsetExec ( cmComplexOnset * p , cmSample_t cdf )
{
p - > df [ p - > dfi + + ] = cdf ;
return cmOkRC ;
}
cmRC_t cmComplexOnsetCalc ( cmComplexOnset * p )
{
// df -= mean(df)
cmVOS_SubVS ( p - > df , p - > frmCnt , cmVOS_Mean ( p - > df , p - > frmCnt ) ) ;
// low pass forward/backward filter df[] into fdf[]
double d = 2 + sqrt ( 2 ) ;
cmReal_t b [ ] = { 1 / d , 2 / d , 1 / d } ;
unsigned bn = sizeof ( b ) / sizeof ( b [ 0 ] ) ;
cmReal_t a [ ] = { 1 , 0 , 7 - 2 * d } ;
unsigned an = sizeof ( a ) / sizeof ( a [ 0 ] ) ;
cmFilterFilterS ( p - > obj . ctx , b , bn , a , an , p - > df , p - > frmCnt , p - > fdf , p - > frmCnt ) ;
// median filter to low-passed filtered fdf[] into df[]
cmVOS_FnThresh ( p - > fdf , p - > frmCnt , p - > medSmpCnt , p - > df , 1 , NULL ) ;
// subtract med filtered signal from the low passed signal.
// fdf[] -= df[];
cmVOS_SubVV ( p - > fdf , p - > frmCnt , p - > df ) ;
cmVOS_SubVS ( p - > fdf , p - > frmCnt , p - > threshold ) ;
cmSample_t * bp = p - > df ,
* ep = bp + p - > frmCnt - 1 ,
* dp = p - > fdf + 1 ;
* bp + + = * ep = 0 ;
for ( ; bp < ep ; bp + + , dp + + )
{
* bp = ( * dp > * ( dp - 1 ) & & * dp > * ( dp + 1 ) & & * dp > 0 ) ? 1 : 0 ;
p - > onrate + = * bp ;
}
p - > onrate / = p - > frmCnt ;
/*
if ( p - > mfp ! = NULL )
{
bp = p - > df ;
ep = bp + p - > frmCnt ;
while ( bp < ep )
cmMtxFileSmpExec ( p - > mfp , bp + + , 1 ) ;
}
*/
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmMfcc * cmMfccAlloc ( cmCtx * c , cmMfcc * ap , double srate , unsigned melBandCnt , unsigned dctCoeffCnt , unsigned binCnt )
{
cmMfcc * p = cmObjAlloc ( cmMfcc , c , ap ) ;
if ( melBandCnt > 0 & & binCnt > 0 & & dctCoeffCnt > 0 )
if ( cmMfccInit ( p , srate , melBandCnt , dctCoeffCnt , binCnt ) ! = cmOkRC )
cmMfccFree ( & p ) ;
return p ;
}
cmRC_t cmMfccFree ( cmMfcc * * pp )
{
cmRC_t rc = cmOkRC ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
cmMfcc * p = * pp ;
if ( ( rc = cmMfccFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > melM ) ;
cmMemPtrFree ( & p - > dctM ) ;
cmMemPtrFree ( & p - > outV ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmMfccInit ( cmMfcc * p , double srate , unsigned melBandCnt , unsigned dctCoeffCnt , unsigned binCnt )
{
cmRC_t rc ;
if ( ( rc = cmMfccFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > melM = cmMemResize ( cmReal_t , p - > melM , melBandCnt * binCnt ) ;
p - > dctM = cmMemResize ( cmReal_t , p - > dctM , dctCoeffCnt * melBandCnt ) ;
p - > outV = cmMemResize ( cmReal_t , p - > outV , dctCoeffCnt ) ;
// each row of the matrix melp contains a mask
cmVOR_MelMask ( p - > melM , melBandCnt , binCnt , srate , kShiftMelFl ) ;
// each row contains melBandCnt elements
cmVOR_DctMatrix ( p - > dctM , dctCoeffCnt , melBandCnt ) ;
p - > melBandCnt = melBandCnt ;
p - > dctCoeffCnt = dctCoeffCnt ;
p - > binCnt = binCnt ;
p - > outN = dctCoeffCnt ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"mfcc");
//if( p->obj.ctx->statsProcPtr != NULL )
// p->mfccSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kMFCC_FId, p->outN );
return cmOkRC ;
}
cmRC_t cmMfccFinal ( cmMfcc * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmMfccExecPower ( cmMfcc * p , const cmReal_t * magPowV , unsigned binCnt )
{
assert ( binCnt = = p - > binCnt ) ;
cmReal_t t [ p - > melBandCnt ] ;
// apply the mel filter mask to the power spectrum
cmVOR_MultVMV ( t , p - > melBandCnt , p - > melM , binCnt , magPowV ) ;
// convert mel bands to dB
cmVOR_PowerToDb ( t , p - > melBandCnt , t ) ;
// decorellate the bands with a DCT
cmVOR_MultVMV ( p - > outV , p - > dctCoeffCnt , p - > dctM , p - > melBandCnt , t ) ;
/*
cmPlotSelectSubPlot ( 0 , 0 ) ;
cmPlotClear ( ) ;
//cmPlotLineS( "power", NULL, magPowV, NULL, 35, NULL, kSolidPlotLineId );
cmPlotLineS ( " mel " , NULL , t0 , NULL , p - > melBandCnt , NULL , kSolidPlotLineId ) ;
cmPlotSelectSubPlot ( 1 , 0 ) ;
cmPlotClear ( ) ;
//cmPlotLineS( "meldb", NULL, t1, NULL, p->melBandCnt, NULL, kSolidPlotLineId );
cmPlotLineS ( " mfcc " , NULL , p - > outV + 1 , NULL , p - > dctCoeffCnt - 1 , NULL , kSolidPlotLineId ) ;
*/
if ( p - > mfp ! = NULL )
cmMtxFileRealExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
cmRC_t cmMfccExecAmplitude ( cmMfcc * p , const cmReal_t * magAmpV , unsigned binCnt )
{
cmReal_t t [ binCnt ] ;
cmVOR_MultVVV ( t , binCnt , magAmpV , magAmpV ) ;
cmMfccExecPower ( p , t , binCnt ) ;
if ( p - > mfp ! = NULL )
cmMtxFileRealExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
enum { cmSonesEqlConBinCnt = kEqualLoudBandCnt , cmSonesEqlConCnt = 13 } ;
cmSones * cmSonesAlloc ( cmCtx * c , cmSones * ap , double srate , unsigned barkBandCnt , unsigned binCnt , unsigned flags )
{
cmSones * p = cmObjAlloc ( cmSones , c , ap ) ;
if ( srate > 0 & & barkBandCnt > 0 & & binCnt > 0 )
if ( cmSonesInit ( p , srate , barkBandCnt , binCnt , flags ) ! = cmOkRC )
cmSonesFree ( & p ) ;
return p ;
}
cmRC_t cmSonesFree ( cmSones * * pp )
{
cmRC_t rc = cmOkRC ;
cmSones * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmSonesFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > ttmV ) ;
cmMemPtrFree ( & p - > sfM ) ;
cmMemPtrFree ( & p - > barkIdxV ) ;
cmMemPtrFree ( & p - > barkCntV ) ;
cmMemPtrFree ( & p - > outV ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmSonesInit ( cmSones * p , double srate , unsigned barkBandCnt , unsigned binCnt , unsigned flags )
{
p - > ttmV = cmMemResize ( cmReal_t , p - > ttmV , binCnt ) ;
p - > sfM = cmMemResize ( cmReal_t , p - > sfM , binCnt * barkBandCnt ) ;
p - > barkIdxV = cmMemResize ( unsigned , p - > barkIdxV , barkBandCnt ) ;
p - > barkCntV = cmMemResize ( unsigned , p - > barkCntV , barkBandCnt ) ;
p - > outV = cmMemResize ( cmReal_t , p - > outV , barkBandCnt ) ;
// calc outer ear filter
cmVOR_TerhardtThresholdMask ( p - > ttmV , binCnt , srate , kNoTtmFlags ) ;
// calc shroeder spreading function
cmVOR_ShroederSpreadingFunc ( p - > sfM , barkBandCnt , srate ) ;
// calc the bin to bark maps
p - > barkBandCnt = cmVOR_BarkMap ( p - > barkIdxV , p - > barkCntV , barkBandCnt , binCnt , srate ) ;
//unsigned i = 0;
//for(; i<barkBandCnt; ++i)
// printf("%i %i %i\n", i+1, barkIdxV[i]+1, barkCntV[i]);
bool elFl = cmIsFlag ( p - > flags , kUseEqlLoudSonesFl ) ;
p - > binCnt = binCnt ;
p - > outN = elFl ? cmSonesEqlConCnt : p - > barkBandCnt ;
p - > overallLoudness = 0 ;
p - > flags = flags ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"sones");
//p->sonesSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kSones_FId, p->outN );
//p->loudSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kLoud_FId, 1 );
return cmOkRC ;
}
cmRC_t cmSonesFinal ( cmSones * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmSonesExec ( cmSones * p , const cmReal_t * magPowV , unsigned binCnt )
{
assert ( binCnt = = p - > binCnt ) ;
// Equal-loudness and phon map from: Y. Wonho, 1999, EMBSD: an objective speech quality measure based on audible distortion,
// equal-loudness contours
double eqlcon [ cmSonesEqlConCnt ] [ cmSonesEqlConBinCnt ] =
{
{ 12 , 7 , 4 , 1 , 0 , 0 , 0 , - 0.5 , - 2 , - 3 , - 7 , - 8 , - 8.5 , - 8.5 , - 8.5 } ,
{ 20 , 17 , 14 , 12 , 10 , 9.5 , 9 , 8.5 , 7.5 , 6.5 , 4 , 3 , 2.5 , 2 , 2.5 } ,
{ 29 , 26 , 23 , 21 , 20 , 19.5 , 19.5 , 19 , 18 , 17 , 15 , 14 , 13.5 , 13 , 13.5 } ,
{ 36 , 34 , 32 , 30 , 29 , 28.5 , 28.5 , 28.5 , 28 , 27.5 , 26 , 25 , 24.5 , 24 , 24.5 } ,
{ 45 , 43 , 41 , 40 , 40 , 40 , 40 , 40 , 40 , 39.5 , 38 , 37 , 36.5 , 36 , 36.5 } ,
{ 53 , 51 , 50 , 49 , 48.5 , 48.5 , 49 , 49 , 49 , 49 , 48 , 47 , 46.5 , 45.5 , 46 } ,
{ 62 , 60 , 59 , 58 , 58 , 58.5 , 59 , 59 , 59 , 59 , 58 , 57.5 , 57 , 56 , 56 } ,
{ 70 , 69 , 68 , 67.5 , 67.5 , 68 , 68 , 68 , 68 , 68 , 67 , 66 , 65.5 , 64.5 , 64.5 } ,
{ 79 , 79 , 79 , 79 , 79 , 79 , 79 , 79 , 78 , 77.5 , 76 , 75 , 74.5 , 73 , 73 } ,
{ 89 , 89 , 89 , 89.5 , 90 , 90 , 90 , 89.5 , 89 , 88.5 , 87 , 86 , 85.5 , 84 , 83.5 } ,
{ 100 , 100 , 100 , 100 , 100 , 99.5 , 99 , 99 , 98.5 , 98 , 96 , 95 , 94.5 , 93.5 , 93 } ,
{ 112 , 112 , 112 , 112 , 111 , 110.5 , 109.5 , 109 , 108.5 , 108 , 106 , 105 , 104.5 , 103 , 102.5 } ,
{ 122 , 122 , 121 , 121 , 120.5 , 120 , 119 , 118 , 117 , 116.5 , 114.5 , 113.5 , 113 , 111 , 110.5 }
} ;
// loudness levels (phone scales)
double phons [ cmSonesEqlConCnt ] = { 0.0 , 10.0 , 20.0 , 30.0 , 40.0 , 50.0 , 60.0 , 70.0 , 80.0 , 90.0 , 100.0 , 110.0 , 120.0 } ;
unsigned i , j ;
cmReal_t t0 [ binCnt ] ;
cmReal_t t1 [ p - > barkBandCnt ] ;
cmReal_t t2 [ p - > barkBandCnt ] ;
unsigned * idxV = p - > barkIdxV ;
unsigned * cntV = p - > barkCntV ;
cmReal_t * sfM = p - > sfM ;
// apply the outer ear filter
cmVOR_MultVVV ( t0 , binCnt , magPowV , p - > ttmV ) ;
// apply the bark frequency warping
for ( i = 0 ; i < p - > barkBandCnt ; + + i )
{
if ( cntV [ i ] = = 0 )
t1 [ i ] = 0 ;
else
{
t1 [ i ] = t0 [ idxV [ i ] ] ;
for ( j = 1 ; j < cntV [ i ] ; + + j )
t1 [ i ] + = t0 [ idxV [ i ] + j ] ;
}
}
// apply the spreading filters
cmVOR_MultVMV ( t2 , p - > barkBandCnt , sfM , p - > barkBandCnt , t1 ) ;
bool elFl = cmIsFlag ( p - > flags , kUseEqlLoudSonesFl ) ;
unsigned bandCnt = elFl ? cmMin ( p - > barkBandCnt , cmSonesEqlConBinCnt ) : p - > barkBandCnt ;
//p->outN = elFl ? cmSonesEqlConCnt : p->barkBandCnt;
p - > overallLoudness = 0 ;
for ( i = 0 ; i < bandCnt ; i + + )
{
// if using the equal-loudness contours begin with the third bark band
// and end with the 18th bark band
unsigned k = elFl ? i + 3 : i ;
if ( k < p - > barkBandCnt )
{
double v = t2 [ k ] ;
// convert to db
v = 10 * log10 ( v < 1 ? 1 : v ) ;
if ( elFl )
{
// db to phons
// see: Y. Wonho, 1999, EMBSD: an objective speech quality measure based on audible distortion,
j = 0 ;
// find the equal loudness curve for this frequency and db level
while ( v > = eqlcon [ j ] [ i ] )
+ + j ;
if ( j = = cmSonesEqlConCnt )
{
cmCtxRtAssertFailed ( & p - > obj , cmArgAssertRC , " Bark band %i is out of range during equal-loudness mapping. " , j ) ;
continue ;
}
// convert db to phons
if ( j = = 0 )
v = phons [ 0 ] ;
else
{
double t1 = ( v - eqlcon [ j - 1 ] [ i ] ) / ( eqlcon [ j ] [ i ] - eqlcon [ j - 1 ] [ i ] ) ;
v = phons [ j - 1 ] + t1 * ( phons [ j ] - phons [ j - 1 ] ) ;
}
}
// convert to sones
// bladon and lindblom, 1981, JASA, modelling the judment of vowel quality differences
if ( v > = 40 )
p - > outV [ i ] = pow ( 2 , ( v - 40 ) / 10 ) ;
else
p - > outV [ i ] = pow ( v / 40 , 2.642 ) ;
p - > overallLoudness + = p - > outV [ i ] ;
}
}
if ( p - > mfp ! = NULL )
cmMtxFileRealExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
void cmSonesTest ( )
{
cmKbRecd kb ;
double srate = 44100 ;
unsigned bandCnt = 23 ;
unsigned binCnt = 513 ;
cmSample_t tv [ binCnt ] ;
cmSample_t sm [ bandCnt * bandCnt ] ;
cmSample_t t [ bandCnt * bandCnt ] ;
unsigned binIdxV [ bandCnt ] ;
unsigned cntV [ bandCnt ] ;
unsigned i ;
cmPlotSetup ( " Sones " , 1 , 1 ) ;
cmVOS_TerhardtThresholdMask ( tv , binCnt , srate , kModifiedTtmFl ) ;
cmVOS_ShroederSpreadingFunc ( sm , bandCnt , srate ) ;
cmVOS_Transpose ( t , sm , bandCnt , bandCnt ) ;
bandCnt = cmVOS_BarkMap ( binIdxV , cntV , bandCnt , binCnt , srate ) ;
for ( i = 0 ; i < bandCnt ; + + i )
printf ( " %i %i %i \n " , i , binIdxV [ i ] , cntV [ i ] ) ;
for ( i = 0 ; i < bandCnt ; + + i )
{
cmPlotLineS ( NULL , NULL , t + ( i * bandCnt ) , NULL , bandCnt , NULL , kSolidPlotLineId ) ;
}
//cmPlotLineS( NULL, NULL, tv, NULL, binCnt, NULL, kSolidPlotLineId );
cmPlotDraw ( ) ;
cmKeyPress ( & kb ) ;
}
//------------------------------------------------------------------------------------------------------------
cmAudioOffsetScale * cmAudioOffsetScaleAlloc ( cmCtx * c , cmAudioOffsetScale * ap , unsigned procSmpCnt , double srate , cmSample_t offset , double rmsWndSecs , double dBref , unsigned flags )
{
cmAudioOffsetScale * p = cmObjAlloc ( cmAudioOffsetScale , c , ap ) ;
if ( procSmpCnt > 0 & & srate > 0 )
if ( cmAudioOffsetScaleInit ( p , procSmpCnt , srate , offset , rmsWndSecs , dBref , flags ) ! = cmOkRC )
cmAudioOffsetScaleFree ( & p ) ;
return p ;
}
cmRC_t cmAudioOffsetScaleFree ( cmAudioOffsetScale * * pp )
{
cmRC_t rc = cmOkRC ;
cmAudioOffsetScale * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmAudioOffsetScaleFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > cBufPtr ) ;
cmMemPtrFree ( & p - > cCntPtr ) ;
cmMemPtrFree ( & p - > outV ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmAudioOffsetScaleInit ( cmAudioOffsetScale * p , unsigned procSmpCnt , double srate , cmSample_t offset , double rmsWndSecs , double dBref , unsigned flags )
{
assert ( procSmpCnt > 0 & & srate > 0 ) ;
cmRC_t rc ;
if ( ( rc = cmAudioOffsetScaleFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > cBufCnt = 0 ;
if ( cmIsFlag ( flags , kRmsAudioScaleFl ) )
{
if ( rmsWndSecs > 0 )
{
unsigned rmsSmpCnt = srate * rmsWndSecs ;
p - > cBufCnt = ( unsigned ) ceil ( rmsSmpCnt / procSmpCnt ) ;
if ( p - > cBufCnt > 0 )
{
p - > cBufPtr = cmMemResizeZ ( cmReal_t , p - > cBufPtr , p - > cBufCnt ) ;
p - > cCntPtr = cmMemResizeZ ( unsigned , p - > cCntPtr , p - > cBufCnt ) ;
}
}
else
{
p - > cBufCnt = 0 ;
p - > cBufPtr = NULL ;
p - > cCntPtr = NULL ;
}
}
p - > cBufIdx = 0 ;
p - > cBufCurCnt = 0 ;
p - > cBufSum = 0 ;
p - > cCntSum = 0 ;
p - > outV = cmMemResize ( cmSample_t , p - > outV , procSmpCnt ) ;
p - > outN = procSmpCnt ;
p - > offset = offset ;
p - > dBref = dBref ;
p - > flags = flags ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"audioOffsetScale");
return cmOkRC ;
}
cmRC_t cmAudioOffsetScaleFinal ( cmAudioOffsetScale * p )
{
//if( p != NULL)
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmAudioOffsetScaleExec ( cmAudioOffsetScale * p , const cmSample_t * sp , unsigned sn )
{
double Pref = 20.0 / 1000000 ; // 20 micro Pascals
cmSample_t * dbp = p - > outV ;
const cmSample_t * dep = dbp + sn ;
double scale = 0 ;
// if no scaling was requested then add offset only
if ( cmIsFlag ( p - > flags , kNoAudioScaleFl ) )
{
while ( dbp < dep )
* dbp + + = * sp + + + p - > offset ;
goto doneLabel ;
}
// if fixed scaling
if ( cmIsFlag ( p - > flags , kFixedAudioScaleFl ) )
{
if ( scale = = 0 )
scale = pow ( 10 , p - > dBref / 20 ) ;
while ( dbp < dep )
* dbp + + = ( * sp + + + p - > offset ) * scale ;
}
else // if RMS scaling
{
double sum = 0 ;
double rms = 0 ;
while ( dbp < dep )
{
double v = ( * sp + + + p - > offset ) / Pref ;
sum + = v * v ;
* dbp + + = v ;
}
// if there is no RMS buffer calc RMS on procSmpCnt samles
if ( p - > cBufCnt = = 0 )
rms = sqrt ( sum / sn ) ;
else
{
p - > cBufSum - = p - > cBufPtr [ p - > cBufIdx ] ;
p - > cBufSum + = sum ;
p - > cCntSum - = p - > cCntPtr [ p - > cBufIdx ] ;
p - > cCntSum + = sn ;
p - > cBufIdx = ( p - > cBufIdx + 1 ) % p - > cBufCnt ;
p - > cBufCurCnt = cmMin ( p - > cBufCurCnt + 1 , p - > cBufCnt ) ;
assert ( p - > cCntSum > 0 ) ;
rms = sqrt ( p - > cBufSum / p - > cCntSum ) ;
}
double sigSPL = 20 * log10 ( rms ) ;
scale = pow ( 10 , ( p - > dBref - sigSPL ) / 20 ) ;
dbp = p - > outV ;
while ( dbp < dep )
* dbp + + * = scale ;
}
doneLabel :
dbp = p - > outV + sn ;
dep = p - > outV + p - > outN ;
while ( dbp < dep )
* dbp + + = 0 ;
if ( p - > mfp ! = NULL )
cmMtxFileSmpExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmSpecMeas * cmSpecMeasAlloc ( cmCtx * c , cmSpecMeas * ap , double srate , unsigned binCnt , unsigned wndFrmCnt , unsigned flags )
{
cmSpecMeas * p = cmObjAlloc ( cmSpecMeas , c , ap ) ;
if ( srate > 0 & & binCnt > 0 )
if ( cmSpecMeasInit ( p , srate , binCnt , wndFrmCnt , flags ) ! = cmOkRC )
cmSpecMeasFree ( & p ) ;
return p ;
}
cmRC_t cmSpecMeasFree ( cmSpecMeas * * pp )
{
cmRC_t rc = cmOkRC ;
cmSpecMeas * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmSpecMeasFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > rmsV ) ;
cmMemPtrFree ( & p - > hfcV ) ;
cmMemPtrFree ( & p - > scnV ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmSpecMeasInit ( cmSpecMeas * p , double srate , unsigned binCnt , unsigned wndFrmCnt , unsigned flags )
{
cmRC_t rc ;
if ( ( rc = cmSpecMeasFinal ( p ) ) ! = cmOkRC )
return rc ;
if ( cmIsFlag ( flags , kUseWndSpecMeasFl ) )
{
p - > rmsV = cmMemResizeZ ( cmReal_t , p - > rmsV , wndFrmCnt ) ;
p - > hfcV = cmMemResizeZ ( cmReal_t , p - > hfcV , wndFrmCnt ) ;
p - > scnV = cmMemResizeZ ( cmReal_t , p - > scnV , wndFrmCnt ) ;
}
p - > rmsSum = 0 ;
p - > hfcSum = 0 ;
p - > scnSum = 0 ;
p - > binCnt = binCnt ;
p - > flags = flags ;
p - > wndFrmCnt = wndFrmCnt ;
p - > frameCnt = 0 ;
p - > frameIdx = 0 ;
p - > binHz = srate / ( ( binCnt - 1 ) * 2 ) ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"specMeas");
//p->rmsSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kRMS_FId, 1);
//p->hfcSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kHFC_FId, 1);
//p->scSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kSC_FId, 1);
//p->ssSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kSS_FId, 1);
return cmOkRC ;
}
cmRC_t cmSpecMeasFinal ( cmSpecMeas * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmSpecMeasExec ( cmSpecMeas * p , const cmReal_t * magPowV , unsigned binCnt )
{
assert ( binCnt = = p - > binCnt ) ;
unsigned i = 0 ;
const cmReal_t * sbp = magPowV ;
const cmReal_t * sep = sbp + binCnt ;
cmReal_t rmsSum = 0 ;
cmReal_t hfcSum = 0 ;
cmReal_t scnSum = 0 ;
cmReal_t ssSum = 0 ;
for ( i = 0 ; sbp < sep ; + + i , + + sbp )
{
rmsSum + = * sbp ;
hfcSum + = * sbp * i ;
scnSum + = * sbp * i * p - > binHz ;
}
p - > frameCnt + + ;
if ( cmIsFlag ( p - > flags , kUseWndSpecMeasFl ) )
{
p - > frameCnt = cmMin ( p - > frameCnt , p - > wndFrmCnt ) ;
cmReal_t * rmsV = p - > rmsV + p - > frameIdx ;
cmReal_t * hfcV = p - > hfcV + p - > frameIdx ;
cmReal_t * scnV = p - > scnV + p - > frameIdx ;
p - > rmsSum - = * rmsV ;
p - > hfcSum - = * hfcV ;
p - > scnSum - = * scnV ;
* rmsV = rmsSum ;
* hfcV = hfcSum ;
* scnV = scnSum ;
p - > frameIdx = ( p - > frameIdx + 1 ) % p - > frameCnt ;
}
p - > rmsSum + = rmsSum ;
p - > hfcSum + = hfcSum ;
p - > scnSum + = scnSum ;
p - > rms = sqrt ( p - > rmsSum / ( p - > binCnt * p - > frameCnt ) ) ;
p - > hfc = p - > hfcSum / ( p - > binCnt * p - > frameCnt ) ;
p - > sc = p - > scnSum / cmMax ( cmReal_EPSILON , p - > rmsSum ) ;
sbp = magPowV ;
for ( i = 0 ; sbp < sep ; + + i )
{
cmReal_t t = ( i * p - > binHz ) - p - > sc ;
ssSum + = * sbp + + * ( t * t ) ;
}
p - > ss = sqrt ( ssSum / cmMax ( cmReal_EPSILON , p - > rmsSum ) ) ;
if ( p - > mfp ! = NULL )
{
cmReal_t a [ 4 ] = { p - > rms , p - > hfc , p - > sc , p - > ss } ;
cmMtxFileRealExec ( p - > mfp , a , 4 ) ;
}
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmSigMeas * cmSigMeasAlloc ( cmCtx * c , cmSigMeas * ap , double srate , unsigned procSmpCnt , unsigned measSmpCnt )
{
cmSigMeas * p = cmObjAlloc ( cmSigMeas , c , ap ) ;
p - > sbp = cmShiftBufAlloc ( c , & p - > shiftBuf , 0 , 0 , 0 ) ;
if ( srate > 0 & & procSmpCnt > 0 & & measSmpCnt > 0 )
if ( cmSigMeasInit ( p , srate , procSmpCnt , measSmpCnt ) ! = cmOkRC )
cmSigMeasFree ( & p ) ;
return p ;
}
cmRC_t cmSigMeasFree ( cmSigMeas * * pp )
{
cmRC_t rc = cmOkRC ;
cmSigMeas * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmSigMeasFinal ( p ) ) ! = cmOkRC )
return rc ;
cmShiftBufFree ( & p - > sbp ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmSigMeasInit ( cmSigMeas * p , double srate , unsigned procSmpCnt , unsigned measSmpCnt )
{
cmRC_t rc ;
if ( ( rc = cmSigMeasFinal ( p ) ) ! = cmOkRC )
return rc ;
if ( procSmpCnt ! = measSmpCnt )
cmShiftBufInit ( p - > sbp , procSmpCnt , measSmpCnt , procSmpCnt ) ;
p - > zcrDelay = 0 ;
p - > srate = srate ;
p - > measSmpCnt = measSmpCnt ;
p - > procSmpCnt = procSmpCnt ;
//p->zcrSpRegId = cmStatsProcReg( p->obj.ctx->statsProcPtr, kZCR_FId, 1 );
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"sigMeas");
return cmOkRC ;
}
cmRC_t cmSigMeasFinal ( cmSigMeas * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmSigMeasExec ( cmSigMeas * p , const cmSample_t * sp , unsigned sn )
{
if ( p - > procSmpCnt ! = p - > measSmpCnt )
{
cmShiftBufExec ( p - > sbp , sp , sn ) ;
sp = p - > sbp - > outV ;
sn = p - > sbp - > wndSmpCnt ;
assert ( p - > sbp - > wndSmpCnt = = p - > measSmpCnt ) ;
}
unsigned zcn = cmVOS_ZeroCrossCount ( sp , sn , NULL ) ;
p - > zcr = ( cmReal_t ) zcn * p - > srate / p - > measSmpCnt ;
if ( p - > mfp ! = NULL )
cmMtxFileRealExec ( p - > mfp , & p - > zcr , 1 ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmSRC * cmSRCAlloc ( cmCtx * c , cmSRC * ap , double srate , unsigned procSmpCnt , unsigned upFact , unsigned dnFact )
{
cmSRC * p = cmObjAlloc ( cmSRC , c , ap ) ;
cmFilterAlloc ( c , & p - > filt , NULL , 0 , NULL , 0 , 0 , NULL ) ;
if ( srate > 0 & & procSmpCnt > 0 )
if ( cmSRCInit ( p , srate , procSmpCnt , upFact , dnFact ) ! = cmOkRC )
cmSRCFree ( & p ) ;
return p ;
}
cmRC_t cmSRCFree ( cmSRC * * pp )
{
cmRC_t rc ;
if ( pp ! = NULL & & * pp ! = NULL )
{
cmSRC * p = * pp ;
if ( ( rc = cmSRCFinal ( p ) ) = = cmOkRC )
{
cmFilter * fp = & p - > filt ;
cmFilterFree ( & fp ) ;
cmMemPtrFree ( & p - > outV ) ;
cmObjFree ( pp ) ;
}
}
return cmOkRC ;
}
cmRC_t cmSRCInit ( cmSRC * p , double srate , unsigned procSmpCnt , unsigned upFact , unsigned dnFact )
{
cmRC_t rc ;
if ( ( rc = cmSRCFinal ( p ) ) ! = cmOkRC )
return rc ;
double hiRate = upFact * srate ;
double loRate = hiRate / dnFact ;
double minRate = cmMin ( loRate , srate ) ;
double fcHz = minRate / 2 ;
double dHz = ( fcHz * .1 ) ; // transition band is 5% of min sample rate
double passHz = fcHz - dHz ;
double stopHz = fcHz ;
double passDb = 0.001 ;
double stopDb = 20 ;
cmFilterInitEllip ( & p - > filt , hiRate , passHz , stopHz , passDb , stopDb , procSmpCnt , NULL ) ;
//printf("CoeffCnt:%i dHz:%f passHz:%f stopHz:%f passDb:%f stopDb:%f\n", p->fir.coeffCnt, dHz, passHz, stopHz, passDb, stopDb );
p - > outN = ( unsigned ) ceil ( procSmpCnt * upFact / dnFact ) ;
p - > outV = cmMemResize ( cmSample_t , p - > outV , p - > outN ) ;
p - > upi = 0 ;
p - > dni = 0 ;
p - > upFact = upFact ;
p - > dnFact = dnFact ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"src");
return cmOkRC ;
}
cmRC_t cmSRCFinal ( cmSRC * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmSRCExec ( cmSRC * p , const cmSample_t * sp , unsigned sn )
{
const cmSample_t * sep = sp + sn ;
cmSample_t * op = p - > outV ;
const cmSample_t * oep = op + p - > outN ;
unsigned iN = sn * p - > upFact ;
unsigned i , j ;
// run the filter at the upsampled rate ...
for ( i = 0 ; i < iN ; + + i )
{
assert ( p - > upi ! = 0 | | sp < sep ) ;
cmSample_t x0 = p - > upi = = 0 ? * sp + + : 0 ,
y0 = x0 * p - > filt . b0 + p - > filt . d [ 0 ] ;
// ... but output at the down sampled rate
if ( p - > dni = = 0 )
{
assert ( op < oep ) ;
* op + + = y0 ;
}
// advance the filter delay line
for ( j = 0 ; j < p - > filt . cn ; + + j )
p - > filt . d [ j ] = p - > filt . b [ j ] * x0 - p - > filt . a [ j ] * y0 + p - > filt . d [ j + 1 ] ;
// update the input/output clocks
p - > upi = ( p - > upi + 1 ) % p - > upFact ;
p - > dni = ( p - > dni + 1 ) % p - > dnFact ;
}
p - > outN = op - p - > outV ;
if ( p - > mfp ! = NULL )
cmMtxFileSmpExec ( p - > mfp , p - > outV , p - > outN ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmConstQ * cmConstQAlloc ( cmCtx * c , cmConstQ * ap , double srate , unsigned minMidiPitch , unsigned maxMidiPitch , unsigned binsPerOctave , double thresh )
{
cmConstQ * p = cmObjAlloc ( cmConstQ , c , ap ) ;
if ( srate > 0 )
if ( cmConstQInit ( p , srate , minMidiPitch , maxMidiPitch , binsPerOctave , thresh ) ! = cmOkRC )
cmConstQFree ( & p ) ;
return p ;
}
cmRC_t cmConstQFree ( cmConstQ * * pp )
{
cmRC_t rc ;
cmConstQ * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmConstQFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > fiV ) ;
cmMemPtrFree ( & p - > foV ) ;
cmMemPtrFree ( & p - > skM ) ;
cmMemPtrFree ( & p - > outV ) ;
cmMemPtrFree ( & p - > magV ) ;
cmMemPtrFree ( & p - > skBegV ) ;
cmMemPtrFree ( & p - > skEndV ) ;
cmObjFree ( pp ) ;
return cmOkRC ;
}
cmRC_t cmConstQInit ( cmConstQ * p , double srate , unsigned minMidiPitch , unsigned maxMidiPitch , unsigned binsPerOctave , double thresh )
{
cmRC_t rc ;
if ( ( rc = cmConstQFinal ( p ) ) ! = cmOkRC )
return rc ;
cmReal_t minHz = cmMidiToHz ( minMidiPitch ) ;
cmReal_t maxHz = cmMidiToHz ( maxMidiPitch ) ;
cmReal_t Q = 1.0 / ( pow ( 2 , ( double ) 1.0 / binsPerOctave ) - 1 ) ;
unsigned K = ( unsigned ) ceil ( binsPerOctave * log2 ( maxHz / minHz ) ) ;
unsigned fftN = cmNextPowerOfTwo ( ( unsigned ) ceil ( Q * srate / minHz ) ) ;
unsigned k = 0 ;
p - > fiV = cmMemResize ( cmComplexR_t , p - > fiV , fftN ) ;
p - > foV = cmMemResize ( cmComplexR_t , p - > foV , fftN ) ;
cmFftPlanR_t plan = cmFft1dPlanAllocR ( fftN , p - > fiV , p - > foV , FFTW_FORWARD , FFTW_ESTIMATE ) ;
p - > wndSmpCnt = fftN ;
p - > constQBinCnt = K ;
p - > binsPerOctave = binsPerOctave ;
p - > skM = cmMemResizeZ ( cmComplexR_t , p - > skM , p - > wndSmpCnt * p - > constQBinCnt ) ;
p - > outV = cmMemResizeZ ( cmComplexR_t , p - > outV , p - > constQBinCnt ) ;
p - > magV = cmMemResizeZ ( cmReal_t , p - > magV , p - > constQBinCnt ) ;
p - > skBegV = cmMemResizeZ ( unsigned , p - > skBegV , p - > constQBinCnt ) ;
p - > skEndV = cmMemResizeZ ( unsigned , p - > skEndV , p - > constQBinCnt ) ;
//p->mfp = cmCtxAllocDebugFile( p->obj.ctx, "constQ");
//printf("hz:%f %f bpo:%i sr:%f thresh:%f Q:%f K%i (cols) fftN:%i (rows)\n", minHz,maxHz,binsPerOctave,srate,thresh,Q,K,fftN);
double * hamm = NULL ;
// note that the bands are created in reverse order
for ( k = 0 ; k < K ; + + k )
{
unsigned iN = ceil ( Q * srate / ( minHz * pow ( 2 , ( double ) k / binsPerOctave ) ) ) ;
unsigned start = fftN / 2 ;
//double hamm[ iN ];
hamm = cmMemResizeZ ( double , hamm , iN ) ;
memset ( p - > fiV , 0 , fftN * sizeof ( cmComplexR_t ) ) ;
memset ( p - > foV , 0 , fftN * sizeof ( cmComplexR_t ) ) ;
cmVOD_Hamming ( hamm , iN ) ;
cmVOD_DivVS ( hamm , iN , iN ) ;
if ( cmIsEvenU ( iN ) )
start - = iN / 2 ;
else
start - = ( iN + 1 ) / 2 ;
//printf("k:%i iN:%i start:%i %i\n",k,iN,start,start+iN-1);
unsigned i = start ;
for ( ; i < = start + iN - 1 ; + + i )
{
double arg = 2.0 * M_PI * Q * ( i - start ) / iN ;
double mag = hamm [ i - start ] ;
p - > fiV [ i - 1 ] = ( mag * cos ( arg ) ) + ( mag * I * sin ( arg ) ) ;
}
cmFftExecuteR ( plan ) ;
// since the bands are created in reverse order they are also stored in reverse order
// (i.e column k-1 is stored first and column 0 is stored last)
i = 0 ;
unsigned minIdx = - 1 ;
unsigned maxIdx = 0 ;
for ( ; i < fftN ; + + i )
{
bool fl = cabs ( p - > foV [ i ] ) < = thresh ;
p - > skM [ ( k * p - > wndSmpCnt ) + i ] = fl ? 0 : p - > foV [ i ] / fftN ;
if ( fl = = false & & minIdx = = - 1 )
minIdx = i ;
if ( fl = = false & & i > maxIdx )
maxIdx = i ;
}
p - > skBegV [ k ] = minIdx ;
p - > skEndV [ k ] = maxIdx ;
}
cmMemPtrFree ( & hamm ) ;
cmFftPlanFreeR ( plan ) ;
return cmOkRC ;
}
cmRC_t cmConstQFinal ( cmConstQ * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmConstQExec ( cmConstQ * p , const cmComplexR_t * ftV , unsigned srcBinCnt )
{
//acVORC_MultVVM( p->outV, p->constQBinCnt,ftV,p->wndSmpCnt, p->skM );
cmReal_t * mbp = p - > magV ;
cmComplexR_t * dbp = p - > outV ;
const cmComplexR_t * dep = p - > outV + p - > constQBinCnt ;
unsigned i = 0 ;
for ( ; dbp < dep ; + + dbp , + + i , + + mbp )
{
const cmComplexR_t * sbp = ftV + p - > skBegV [ i ] ;
const cmComplexR_t * kp = p - > skM + ( i * p - > wndSmpCnt ) + p - > skBegV [ i ] ;
const cmComplexR_t * ep = kp + ( p - > skEndV [ i ] - p - > skBegV [ i ] ) + 1 ;
* dbp = 0 ;
while ( kp < ep )
* dbp + = * sbp + + * * kp + + ;
* mbp = cmCabsR ( * dbp ) ;
}
if ( p - > mfp ! = NULL )
cmMtxFileComplexExec ( p - > mfp , p - > outV , p - > constQBinCnt , 1 ) ;
return cmOkRC ;
}
void cmConstQTest ( cmConstQ * p )
{
cmKbRecd kb ;
unsigned i , j ;
cmSample_t * t = cmMemAlloc ( cmSample_t , p - > wndSmpCnt ) ;
for ( i = 0 ; i < p - > constQBinCnt ; + + i )
{
for ( j = 0 ; j < p - > wndSmpCnt ; + + j )
t [ j ] = cabs ( p - > skM [ ( i * p - > wndSmpCnt ) + j ] ) ;
//cmPlotClear();
cmPlotLineS ( NULL , NULL , t , NULL , 500 , NULL , kSolidPlotLineId ) ;
}
cmPlotDraw ( ) ;
cmKeyPress ( & kb ) ;
cmMemPtrFree ( & t ) ;
}
//------------------------------------------------------------------------------------------------------------
cmHpcp * cmTunedHpcpAlloc ( cmCtx * c , cmHpcp * ap , unsigned binsPerOctave , unsigned constQBinCnt , unsigned cqMinMidiPitch , unsigned frameCnt , unsigned medFiltOrder )
{
cmHpcp * p = cmObjAlloc ( cmHpcp , c , ap ) ;
if ( binsPerOctave > 0 & & constQBinCnt > > 0 )
if ( cmTunedHpcpInit ( p , binsPerOctave , constQBinCnt , cqMinMidiPitch , frameCnt , medFiltOrder ) ! = cmOkRC )
cmTunedHpcpFree ( & p ) ;
return p ;
}
cmRC_t cmTunedHpcpFree ( cmHpcp * * pp )
{
cmRC_t rc = cmOkRC ;
cmHpcp * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmTunedHpcpFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > hpcpM ) ;
cmMemPtrFree ( & p - > fhpcpM ) ;
cmMemPtrFree ( & p - > histV ) ;
cmMemPtrFree ( & p - > outM ) ;
cmMemPtrFree ( & p - > meanV ) ;
cmMemPtrFree ( & p - > varV ) ;
cmObjFree ( pp ) ;
return cmOkRC ;
}
cmRC_t cmTunedHpcpInit ( cmHpcp * p , unsigned binsPerOctave , unsigned constQBinCnt , unsigned cqMinMidiPitch , unsigned frameCnt , unsigned medFiltOrder )
{
assert ( binsPerOctave % kStPerOctave = = 0 ) ;
assert ( cmIsOddU ( binsPerOctave / kStPerOctave ) ) ;
cmRC_t rc ;
if ( ( rc = cmTunedHpcpFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > histN = binsPerOctave / kStPerOctave ;
p - > hpcpM = cmMemResizeZ ( cmReal_t , p - > hpcpM , frameCnt * binsPerOctave ) ;
p - > fhpcpM = cmMemResizeZ ( cmReal_t , p - > fhpcpM , binsPerOctave * frameCnt ) ;
p - > histV = cmMemResizeZ ( unsigned , p - > histV , p - > histN ) ;
p - > outM = cmMemResizeZ ( cmReal_t , p - > outM , kStPerOctave * frameCnt ) ;
p - > meanV = cmMemResizeZ ( cmReal_t , p - > meanV , kStPerOctave ) ;
p - > varV = cmMemResizeZ ( cmReal_t , p - > varV , kStPerOctave ) ;
p - > constQBinCnt = constQBinCnt ;
p - > binsPerOctave = binsPerOctave ;
p - > frameCnt = frameCnt ;
p - > frameIdx = 0 ;
p - > cqMinMidiPitch = cqMinMidiPitch ;
p - > medFiltOrder = medFiltOrder ;
//p->mf0p = cmCtxAllocDebugFile(p->obj.ctx,"hpcp");
//p->mf1p = cmCtxAllocDebugFile(p->obj.ctx,"fhpcp");
//p->mf2p = cmCtxAllocDebugFile(p->obj.ctx,"chroma");
return cmOkRC ;
}
cmRC_t cmTunedHpcpFinal ( cmHpcp * p )
{
/*
if ( p ! = NULL )
{
cmCtxFreeDebugFile ( p - > obj . ctx , & p - > mf0p ) ;
cmCtxFreeDebugFile ( p - > obj . ctx , & p - > mf1p ) ;
cmCtxFreeDebugFile ( p - > obj . ctx , & p - > mf2p ) ;
}
*/
return cmOkRC ;
}
cmRC_t cmTunedHpcpExec ( cmHpcp * p , const cmComplexR_t * cqp , unsigned cqn )
{
assert ( cqn = = p - > constQBinCnt ) ;
// if there is no space to store the output then do nothing
if ( p - > frameIdx > = p - > frameCnt )
return cmOkRC ;
unsigned octCnt = ( unsigned ) floor ( p - > constQBinCnt / p - > binsPerOctave ) ;
unsigned i ;
cmReal_t hpcpV [ p - > binsPerOctave + 2 ] ;
unsigned idxV [ p - > binsPerOctave ] ;
unsigned binsPerSt = p - > binsPerOctave / kStPerOctave ;
// Notice that the first and last elements of p->hpcp are reserved for
// use in producing the appeareance of circularity for the peak picking
// algorithm. The cmtual hpcp[] data begins on the index 1 (not 0) and
// ends on p->binsPerOctave (not p->binsPerOctave-1).
// sum the constQBinCnt constant Q bins into binsPerOctave bins to form the HPCP
for ( i = 0 ; i < p - > binsPerOctave ; + + i )
{
cmReal_t sum = 0 ;
const cmComplexR_t * sbp = cqp + i ;
const cmComplexR_t * sep = cqp + ( octCnt * p - > binsPerOctave ) ;
for ( ; sbp < sep ; sbp + = p - > binsPerOctave )
sum + = cmCabsR ( * sbp ) ;
hpcpV [ i + 1 ] = sum ;
}
// shift the lowest ST center bin to (binsPerSt+1)/2 such that an equal number of
// flat and sharp bins are above an below it
int rotateCnt = ( ( binsPerSt + 1 ) / 2 ) - 1 ;
// shift pitch class C to the lowest semitone boundary
rotateCnt - = ( 48 - ( int ) p - > cqMinMidiPitch ) * binsPerSt ;
// perform the shift
cmVOR_Rotate ( hpcpV + 1 , p - > binsPerOctave , rotateCnt ) ;
// duplicate the first and last bin to produce circularity in the hpcp
hpcpV [ 0 ] = hpcpV [ p - > binsPerOctave ] ;
hpcpV [ p - > binsPerOctave + 1 ] = hpcpV [ 1 ] ;
// locate the indexes of the positive peaks in the hpcp
unsigned pkN = cmVOR_PeakIndexes ( idxV , p - > binsPerOctave , hpcpV , p - > binsPerOctave , 0 ) ;
// Convert the peak indexes to values in the range 0 to binsPerSet-1
// If stPerBin == 3 : 0=flat 1=in tune 2=sharp
cmVOU_Mod ( idxV , pkN , binsPerSt ) ;
// Form a histogram to keep count of the number of flat,in-tune and sharp peaks
cmVOU_Hist ( p - > histV , binsPerSt , idxV , pkN ) ;
// store the hpcpV[] to the row p->hpcpM[p->frameIdx,:]
cmVOR_CopyN ( p - > hpcpM + p - > frameIdx , p - > binsPerOctave , p - > frameCnt , hpcpV + 1 , 1 ) ;
// write the hpcp debug file
if ( p - > mf0p ! = NULL )
cmMtxFileRealExecN ( p - > mf0p , p - > hpcpM + p - > frameIdx , p - > binsPerOctave , p - > frameCnt ) ;
p - > frameIdx + + ;
return cmOkRC ;
}
cmRC_t cmTunedHpcpTuneAndFilter ( cmHpcp * p )
{
// note: p->frameIdx now holds the cmtual count of frames in p->hpcpA[].
// p->frameCnt holds the allocated count of frames in p->hpcpA[].
unsigned i , j ;
// filter each column of hpcpA[] into each row of fhpcpA[]
for ( i = 0 ; i < p - > binsPerOctave ; + + i )
{
cmVOR_MedianFilt ( p - > hpcpM + ( i * p - > frameCnt ) , p - > frameIdx , p - > medFiltOrder , p - > fhpcpM + i , p - > binsPerOctave ) ;
// write the fhpcp[i,:] to the debug file
if ( p - > mf1p ! = NULL )
cmMtxFileRealExecN ( p - > mf1p , p - > fhpcpM + i , p - > frameIdx , p - > binsPerOctave ) ;
}
unsigned binsPerSt = p - > histN ;
assert ( ( binsPerSt > 0 ) & & ( cmIsOddU ( binsPerSt ) ) ) ;
unsigned maxIdx = cmVOU_MaxIndex ( p - > histV , binsPerSt , 1 ) ;
int tuneShift = - ( maxIdx - ( ( binsPerSt + 1 ) / 2 ) ) ;
cmReal_t gaussWndV [ binsPerSt ] ;
// generate a gaussian window
cmVOR_GaussWin ( gaussWndV , binsPerSt , 2.5 ) ;
// Rotate the window to apply tuning via the weighted sum operation below
// (the result will be equivalent to rotating p->fhpcpM[] prior to reducing the )
cmVOR_Rotate ( gaussWndV , binsPerSt , tuneShift ) ;
// zero the meanV[] before summing into it
cmVOR_Fill ( p - > meanV , kStPerOctave , 0 ) ;
// for each frame
for ( i = 0 ; i < p - > frameIdx ; + + i )
{
// for each semitone
for ( j = 0 ; j < kStPerOctave ; + + j )
{
// reduce each semitone to a single value by forming a weighted sum of all the assoc'd bins
cmReal_t sum = cmVOR_MultSumVV ( gaussWndV , p - > fhpcpM + ( i * p - > binsPerOctave ) + ( j * binsPerSt ) , binsPerSt ) ;
// store time-series output to the ith column
p - > outM [ ( i * kStPerOctave ) + j ] = sum ;
// calc the sum of all chroma values in bin j.
p - > meanV [ j ] + = sum ;
}
// write the chroma debug file
if ( p - > mf2p ! = NULL )
cmMtxFileRealExec ( p - > mf2p , p - > outM + ( i * kStPerOctave ) , kStPerOctave ) ;
}
// form the chroma mean from the sum calc'd above
cmVOR_DivVS ( p - > meanV , kStPerOctave , p - > frameIdx ) ;
// variance
for ( j = 0 ; j < kStPerOctave ; + + j )
p - > varV [ j ] = cmVOR_VarianceN ( p - > outM + j , p - > frameIdx , kStPerOctave , p - > meanV + j ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
/*
cmStatsProc * cmStatsProcAlloc ( cmCtx * c , cmStatsProc * p , unsigned wndEleCnt , unsigned flags )
{
cmStatsProc * op = cmObjAlloc ( cmStatsProc , c , p ) ;
if ( wndEleCnt > 0 )
if ( cmStatsProcInit ( op , wndEleCnt , flags ) ! = cmOkRC )
cmStatsProcFree ( & op ) ;
if ( op ! = NULL )
cmCtxSetStatsProc ( c , op ) ;
return op ;
}
cmRC_t cmStatsProcFree ( cmStatsProc * * pp )
{
cmRC_t rc = cmOkRC ;
cmStatsProc * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmStatsProcFinal ( p ) ) ! = cmOkRC )
return rc ;
cmCtxSetStatsProc ( p - > obj . ctx , NULL ) ; // complement to cmSetStatsProc() in cmStatsProcAlloc()
cmMemPtrFree ( & p - > regArrayV ) ;
cmMemPtrFree ( & p - > m ) ;
cmMemPtrFree ( & p - > sumV ) ;
cmMemPtrFree ( & p - > meanV ) ;
cmMemPtrFree ( & p - > varV ) ;
cmObjFree ( pp ) ;
return cmOkRC ;
}
cmRC_t cmStatsProcInit ( cmStatsProc * p , unsigned wndEleCnt , unsigned flags )
{
cmRC_t rc ;
if ( ( rc = cmStatsProcFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > wndEleCnt = wndEleCnt ;
p - > dimCnt = 0 ;
p - > curIdx = 0 ;
p - > curCnt = 1 ;
p - > flags = flags ;
p - > execCnt = 0 ;
p - > regArrayN = 0 ;
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"statsProc");
return rc ;
}
cmRC_t cmStatsProcFinal ( cmStatsProc * p )
{
if ( p ! = NULL )
cmCtxFreeDebugFile ( p - > obj . ctx , & p - > mfp ) ;
return cmOkRC ;
}
unsigned cmStatsProcReg ( cmStatsProc * p , unsigned featId , unsigned featEleCnt )
{
cmStatsProcRecd r ;
r . featId = featId ;
r . idx = p - > dimCnt ;
r . cnt = featEleCnt ;
p - > dimCnt + = featEleCnt ;
//unsigned i;
// printf("B:\n");
//for(i=0; i<p->regArrayN; ++i)
// printf("fid:%i idx:%i cnt:%i : fid:%i cnt:%i\n", p->regArrayV[i].featId,p->regArrayV[i].idx,p->regArrayV[i].cnt,featId,featEleCnt);
//printf("\nA:\n");
p - > regArrayV = cmMemResizePZ ( cmStatsProcRecd , p - > regArrayV , p - > regArrayN + 1 ) ;
p - > regArrayV [ p - > regArrayN ] = r ;
p - > regArrayN + + ;
//for(i=0; i<p->regArrayN; ++i)
// printf("fid:%i idx:%i cnt:%i : fid:%i cnt:%i\n", p->regArrayV[i].featId,p->regArrayV[i].idx,p->regArrayV[i].cnt,featId,featEleCnt);
//printf("\n");
return p - > regArrayN - 1 ; // return the index of the new reg recd
}
const cmStatsProcRecd * cmStatsProcRecdPtr ( cmStatsProc * p , unsigned regId )
{
assert ( regId < p - > regArrayN ) ;
return p - > regArrayV + regId ;
}
cmRC_t cmStatsProcExecD ( cmStatsProc * p , unsigned regId , const double v [ ] , unsigned vCnt )
{
cmRC_t rc = cmOkRC ;
// on the first pass allcoate the storage buffer (m) and vectors (sumV,meanV and varV)
if ( p - > execCnt = = 0 )
{
p - > sumV = cmMemResizeZ ( double , p - > sumV , p - > dimCnt ) ;
p - > meanV = cmMemResizeZ ( double , p - > meanV , p - > dimCnt ) ;
p - > varV = cmMemResizeZ ( double , p - > varV , p - > dimCnt ) ;
p - > m = cmMemResizeZ ( double , p - > m , p - > dimCnt * p - > wndEleCnt ) ;
}
// if the storage matrix is full
if ( p - > curIdx = = p - > wndEleCnt )
return rc ;
// get the pointer to this data source reg recd
assert ( regId < p - > regArrayN ) ;
cmStatsProcRecd * r = p - > regArrayV + regId ;
// the dimensionality of the incoming data must be <= the registered dimensionality
assert ( r - > cnt < = vCnt ) ;
unsigned dimIdx = r - > idx ;
bool updateFl = cmIsFlag ( p - > flags , kUpdateOnExecStatProcFl ) ;
double * sbp = p - > sumV + dimIdx ; // sum base ptr
// mbp point to a segment (mbp[vCnt]) in column p->curIdx
double * mbp = p - > m + ( p - > curIdx * p - > dimCnt ) + dimIdx ; // mem col base ptr
const double * mep = p - > m + p - > dimCnt * p - > wndEleCnt ;
// decr the current col segment from the sum
if ( updateFl )
cmVOD_SubVV ( sbp , vCnt , mbp ) ;
assert ( p - > m < = mbp & & mbp < mep & & p - > m < = mbp + vCnt & & mbp + vCnt < = mep ) ;
// copy in the incoming values to mem col segment
cmVOD_Copy ( mbp , vCnt , v ) ;
if ( updateFl )
{
// incr the sum from the incoming value
cmVOD_AddVV ( sbp , vCnt , mbp ) ;
// use the new sum to compute new mean values
cmVOD_DivVVS ( p - > meanV + dimIdx , vCnt , sbp , p - > curCnt ) ;
// update the variance - cmross each row
unsigned di ;
for ( di = dimIdx ; di < dimIdx + vCnt ; + + di )
p - > varV [ di ] = cmVOD_VarianceN ( p - > m + dimIdx , p - > curCnt , p - > dimCnt , p - > meanV + dimIdx ) ;
}
+ + p - > execCnt ;
return cmOkRC ;
}
cmRC_t cmStatsProcExecF ( cmStatsProc * p , unsigned regId , const float v [ ] , unsigned vCnt )
{
double dv [ vCnt ] ;
cmVOD_CopyF ( dv , vCnt , v ) ;
cmStatsProcExecD ( p , regId , dv , vCnt ) ;
return cmOkRC ;
}
cmRC_t cmStatsProcCalc ( cmStatsProc * p )
{
unsigned colCnt = cmMin ( p - > curCnt , p - > wndEleCnt ) ;
unsigned i = 0 ;
cmVOD_Fill ( p - > sumV , p - > dimCnt , 0 ) ;
// sum the ith col of p->m[] into p->sumV[i]
for ( ; i < colCnt ; + + i )
{
cmVOD_AddVV ( p - > sumV , p - > dimCnt , p - > m + ( i * p - > dimCnt ) ) ;
if ( p - > mfp ! = NULL )
cmMtxFileDoubleExec ( p - > mfp , p - > sumV , p - > dimCnt , 1 ) ;
}
// calc the mean of each row
cmVOD_DivVVS ( p - > meanV , p - > dimCnt , p - > sumV , colCnt ) ;
// calc the variance cmross each row
for ( i = 0 ; i < p - > dimCnt ; + + i )
p - > varV [ i ] = cmVOD_VarianceN ( p - > m + i , colCnt , p - > dimCnt , p - > meanV + i ) ;
return cmOkRC ;
}
cmRC_t cmStatsProcAdvance ( cmStatsProc * p )
{
+ + p - > curIdx ;
if ( p - > curIdx > p - > wndEleCnt )
p - > curIdx = 0 ;
p - > curCnt = cmMin ( p - > curCnt + 1 , p - > wndEleCnt ) ;
return cmOkRC ;
}
void cmStatsProcTest ( cmVReportFuncPtr_t vReportFunc )
{
enum
{
wndEleCnt = 7 ,
dDimCnt = 3 ,
fDimCnt = 2 ,
dimCnt = dDimCnt + fDimCnt ,
kTypeId0 = 0 ,
kTypeId1 = 1
} ;
unsigned flags = 0 ;
unsigned i ;
double dd [ dDimCnt * wndEleCnt ] =
{
0 , 1 , 2 ,
3 , 4 , 5 ,
6 , 7 , 8 ,
9 , 10 , 11 ,
12 , 13 , 14 ,
15 , 16 , 17 ,
18 , 19 , 20
} ;
float fd [ 14 ] =
{
0 , 1 ,
2 , 3 ,
4 , 5 ,
6 , 7 ,
8 , 9 ,
10 , 11 ,
12 , 13
} ;
cmCtx c ;
cmCtxInit ( & c , vReportFunc , vReportFunc , NULL ) ;
cmStatsProc * p = cmStatsProcAlloc ( & c , NULL , wndEleCnt , flags ) ;
unsigned regId0 = cmStatsProcReg ( p , kTypeId0 , dDimCnt ) ;
unsigned regId1 = cmStatsProcReg ( p , kTypeId1 , fDimCnt ) ;
for ( i = 0 ; i < wndEleCnt ; + + i )
{
cmStatsProcExecD ( p , regId0 , dd + ( i * dDimCnt ) , dDimCnt ) ;
cmStatsProcExecF ( p , regId1 , fd + ( i * fDimCnt ) , fDimCnt ) ;
cmStatsProcAdvance ( p ) ;
}
cmStatsProcCalc ( p ) ;
cmVOD_PrintE ( vReportFunc , 1 , p - > dimCnt , p - > meanV ) ;
cmVOD_PrintE ( vReportFunc , 1 , p - > dimCnt , p - > varV ) ;
cmStatsProcFree ( & p ) ;
}
*/
//------------------------------------------------------------------------------------------------------------
cmBeatHist * cmBeatHistAlloc ( cmCtx * c , cmBeatHist * ap , unsigned frmCnt )
{
cmBeatHist * p = cmObjAlloc ( cmBeatHist , c , ap ) ;
p - > fft = cmFftAllocRR ( c , NULL , NULL , 0 , kToPolarFftFl ) ;
p - > ifft = cmIFftAllocRR ( c , NULL , 0 ) ;
if ( frmCnt > 0 )
if ( cmBeatHistInit ( p , frmCnt ) ! = cmOkRC )
cmBeatHistFree ( & p ) ;
return p ;
}
cmRC_t cmBeatHistFree ( cmBeatHist * * pp )
{
cmRC_t rc = cmOkRC ;
cmBeatHist * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmBeatHistFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > m ) ;
cmMemPtrFree ( & p - > H ) ;
cmMemPtrFree ( & p - > df ) ;
cmMemPtrFree ( & p - > fdf ) ;
cmMemPtrFree ( & p - > histV ) ;
cmFftFreeRR ( & p - > fft ) ;
cmIFftFreeRR ( & p - > ifft ) ;
cmObjFree ( & p ) ;
return rc ;
}
void _cmBeatHistInitH ( cmReal_t * H , unsigned hrn , unsigned hcn , unsigned ri , unsigned c0 , unsigned c1 )
{
unsigned ci ;
for ( ci = c0 ; ci < = c1 ; + + ci )
H [ ( ci * hrn ) + ri ] = 1 ;
}
cmRC_t cmBeatHistInit ( cmBeatHist * p , unsigned frmCnt )
{
cmRC_t rc ;
unsigned i , j , k ;
enum { kLagFact = 4 , kHistBinCnt = 15 , kHColCnt = 128 } ;
if ( ( rc = cmBeatHistFinal ( p ) ) ! = cmOkRC )
return rc ;
p - > frmCnt = frmCnt ;
p - > maxLagCnt = ( unsigned ) floor ( p - > frmCnt / kLagFact ) ;
p - > histBinCnt = kHistBinCnt ;
p - > hColCnt = kHColCnt ;
p - > dfi = 0 ;
unsigned cfbMemN = p - > frmCnt * p - > maxLagCnt ;
unsigned hMemN = p - > histBinCnt * kHColCnt ;
//cmArrayResizeVZ(p->obj.ctx,&p->cfbMem, cmReal_t, &p->m, cfbMemN, &p->H, hMemN, NULL);
p - > m = cmMemResizeZ ( cmReal_t , p - > m , cfbMemN ) ;
p - > H = cmMemResizeZ ( cmReal_t , p - > H , hMemN ) ;
//p->df = cmArrayResizeZ(c,&p->dfMem, 2*p->frmCnt + kHistBinCnt, cmReal_t);
//p->fdf = p->df + p->frmCnt;
//p->histV = p->fdf + p->frmCnt;
//cmArrayResizeVZ(p->obj.ctx, &p->dfMem, cmReal_t, &p->df, p->frmCnt, &p->fdf, p->frmCnt, &p->histV, kHistBinCnt, NULL );
p - > df = cmMemResizeZ ( cmReal_t , p - > df , p - > frmCnt ) ;
p - > fdf = cmMemResizeZ ( cmReal_t , p - > fdf , p - > frmCnt ) ;
p - > histV = cmMemResizeZ ( cmReal_t , p - > histV , kHistBinCnt ) ;
cmFftInitRR ( p - > fft , NULL , cmNextPowerOfTwo ( 2 * frmCnt ) , kToPolarFftFl ) ;
cmIFftInitRR ( p - > ifft , p - > fft - > binCnt ) ;
// initialize H
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 0 , 103 , 127 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 1 , 86 , 102 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 2 , 73 , 85 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 3 , 64 , 72 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 4 , 57 , 63 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 5 , 51 , 56 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 6 , 46 , 50 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 7 , 43 , 45 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 8 , 39 , 42 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 9 , 36 , 38 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 10 , 32 , 35 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 11 , 28 , 31 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 12 , 25 , 27 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 13 , 21 , 24 ) ;
_cmBeatHistInitH ( p - > H , p - > histBinCnt , p - > hColCnt , 14 , 11 , 20 ) ;
// for each column
for ( i = 0 ; i < p - > maxLagCnt ; + + i )
{
// for each lag group
for ( j = 0 ; j < kLagFact ; + + j )
{
for ( k = 0 ; k < = 2 * j ; + + k )
{
unsigned idx = ( i * p - > frmCnt ) + ( i * j ) + i + k ;
if ( idx < cfbMemN )
p - > m [ idx ] = 1.0 / ( 2 * j + 1 ) ;
}
}
}
double g [ p - > maxLagCnt ] ;
double g_max = 0 ;
double b = 43 ;
b = b * b ;
for ( i = 0 ; i < p - > maxLagCnt ; + + i )
{
double n = i + 1 ;
g [ i ] = n / b * exp ( - ( n * n ) / ( 2 * b ) ) ;
if ( g [ i ] > g_max )
g_max = g [ i ] ;
}
// normalize g[]
cmVOD_DivVS ( g , p - > maxLagCnt , g_max ) ;
// for each column of p->m[]
for ( i = 0 ; i < p - > maxLagCnt ; + + i )
{
double gg = g [ i ] ;
k = i * p - > frmCnt ;
for ( j = 0 ; j < p - > frmCnt ; + + j )
p - > m [ k + j ] * = gg ;
}
//p->mfp = cmCtxAllocDebugFile(p->obj.ctx,"beatHist");
return cmOkRC ;
}
cmRC_t cmBeatHistFinal ( cmBeatHist * p )
{
//if( p != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
return cmOkRC ;
}
cmRC_t cmBeatHistExec ( cmBeatHist * p , cmSample_t df )
{
if ( p - > dfi < p - > frmCnt )
p - > df [ p - > dfi + + ] = df ;
return cmOkRC ;
}
cmRC_t cmBeatHistCalc ( cmBeatHist * p )
{
unsigned i ;
// df -= mean(df)
cmVOR_SubVS ( p - > df , p - > frmCnt , cmVOR_Mean ( p - > df , p - > frmCnt ) ) ;
//cmPlotLineR( "dfm", NULL, p->df, NULL, p->frmCnt, NULL, kSolidPlotLineId );
// take alpha norm of df
double alpha = 9 ;
cmVOR_DivVS ( p - > df , p - > frmCnt , cmVOR_AlphaNorm ( p - > df , p - > frmCnt , alpha ) ) ;
//cmPlotLineS( "dfd", NULL, p->df, NULL, p->frmCnt, NULL, kSolidPlotLineId );
// low pass forward/backward filter df[] into fdf[]
cmReal_t b [ ] = { 0.1600 , 0.3200 , 0.1600 } ;
unsigned bn = sizeof ( b ) / sizeof ( b [ 0 ] ) ;
cmReal_t a [ ] = { 1.0000 , - 0.5949 , 0.2348 } ;
unsigned an = sizeof ( a ) / sizeof ( a [ 0 ] ) ;
cmFilterFilterR ( p - > obj . ctx , b , bn , a , an , p - > df , p - > frmCnt , p - > fdf , p - > frmCnt ) ;
//cmPlotLineS( "fdf", NULL, p->fdf, NULL, p->frmCnt, NULL, kSolidPlotLineId );
// median filter to low-passed filtered fdf[] into df[]
cmVOR_FnThresh ( p - > fdf , p - > frmCnt , 16 , p - > df , 1 , NULL ) ;
// subtract med filtered signal from the low pa1ssed signal.
// fdf[] -= df[];
cmVOR_SubVV ( p - > fdf , p - > frmCnt , p - > df ) ;
// half-wave rectify fdf[] = set all negative values in fdf[] to zero.
cmVOR_HalfWaveRectify ( p - > fdf , p - > frmCnt , p - > fdf ) ;
//cmPlotLineS( "meddf", NULL, p->fdf, NULL, p->frmCnt, NULL, kSolidPlotLineId );
// take FT of fdf[]
cmFftExecRR ( p - > fft , p - > fdf , p - > frmCnt ) ;
// square FT magn.
cmVOR_PowVS ( p - > fft - > magV , p - > fft - > binCnt , 2 ) ;
//cmPlotLineS( "mag", NULL, p->fft->magV, NULL, p->fft->binCnt, NULL, kSolidPlotLineId );
// take the IFFT of the squared magnitude vector.
cmVOR_Fill ( p - > fft - > phsV , p - > fft - > binCnt , 0 ) ;
cmIFftExecRectRR ( p - > ifft , p - > fft - > magV , p - > fft - > phsV ) ;
// Matlab automatically provides this scaling as part of the IFFT.
cmVOR_DivVS ( p - > ifft - > outV , p - > ifft - > outN , p - > ifft - > outN ) ;
// remove bias for short periods from CMF
for ( i = 0 ; i < p - > frmCnt ; + + i )
p - > ifft - > outV [ i ] / = ( p - > frmCnt - i ) ;
//cmPlotLineS( "cm", NULL, p->ifft->outV, NULL, p->frmCnt, NULL, kSolidPlotLineId );
// apply comb filter to the CMF and store result in df[maxLagCnt]
cmVOR_MultVMtV ( p - > df , p - > maxLagCnt , p - > m , p - > frmCnt , p - > ifft - > outV ) ;
//acPlotLineS( "cfb", NULL, p->df, NULL, p->maxLagCnt, NULL, kSolidPlotLineId );
//acVOR_Print(p->obj.err.rpt,1,p->maxLagCnt,p->df);
assert ( p - > maxLagCnt = = p - > hColCnt ) ;
cmVOR_MultVMV ( p - > histV , p - > histBinCnt , p - > H , p - > hColCnt , p - > df ) ;
cmReal_t bins [ ] = { 25 , 17 , 13 , 9 , 7 , 6 , 5 , 3 , 4 , 3 , 4 , 4 , 3 , 4 , 10 } ;
cmVOR_DivVV ( p - > histV , p - > histBinCnt , bins ) ;
//cmPlotLineS( "cfb", NULL, p->histV, NULL, p->histBinCnt, NULL, kSolidPlotLineId );
if ( p - > mfp ! = NULL )
cmMtxFileRealExec ( p - > mfp , p - > histV , p - > histBinCnt ) ;
return cmOkRC ;
}
//------------------------------------------------------------------------------------------------------------
cmGmm_t * cmGmmAlloc ( cmCtx * c , cmGmm_t * ap , unsigned K , unsigned D , const cmReal_t * gM , const cmReal_t * uM , const cmReal_t * sMM , unsigned uflags )
{
cmGmm_t * p = cmObjAlloc ( cmGmm_t , c , ap ) ;
if ( K > 0 & & D > 0 )
if ( cmGmmInit ( p , K , D , gM , uM , sMM , uflags ) ! = cmOkRC )
cmGmmFree ( & p ) ;
return p ;
}
cmRC_t cmGmmFree ( cmGmm_t * * pp )
{
cmRC_t rc = cmOkRC ;
cmGmm_t * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmGmmFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > gV ) ;
cmMemPtrFree ( & p - > uM ) ;
cmMemPtrFree ( & p - > sMM ) ;
cmMemPtrFree ( & p - > isMM ) ;
cmMemPtrFree ( & p - > uMM ) ;
cmMemPtrFree ( & p - > logDetV ) ;
cmMemPtrFree ( & p - > t ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t _cmGmmUpdateCovar ( cmGmm_t * p , const cmReal_t * sMM )
{
unsigned i ;
if ( sMM = = NULL )
return cmOkRC ;
unsigned De2 = p - > D * p - > D ;
unsigned KDe2 = p - > K * De2 ;
cmVOR_Copy ( p - > sMM , KDe2 , sMM ) ;
cmVOR_Copy ( p - > isMM , KDe2 , sMM ) ;
cmVOR_Copy ( p - > uMM , KDe2 , sMM ) ;
//if( cmIsFlag(p->uflags,cmGmmCovarNoProcFl) )
// return cmOkRC;
// for each component
for ( i = 0 ; i < p - > K ; + + i )
{
cmReal_t * is = p - > isMM + i * De2 ;
cmReal_t * u = p - > uMM + i * De2 ;
cmReal_t * r ;
// if the covariance matrix is diagnal
if ( cmIsFlag ( p - > uflags , cmGmmDiagFl ) )
{
p - > logDetV [ i ] = cmVOR_LogDetDiagM ( is , p - > D ) ; // calc the det. of diag. covar. mtx
r = cmVOR_InvDiagM ( is , p - > D ) ; // calc the inverse in place
}
else
{
p - > logDetV [ i ] = cmVOR_LogDetM ( is , p - > D ) ; // calc the det. of covar mtx
r = cmVOR_InvM ( is , p - > D ) ; // calc the inverse in place
}
if ( fabs ( p - > logDetV [ i ] ) < 1e-20 )
{
cmCtxPrint ( p - > obj . ctx , " %i \n " , i ) ;
cmVOR_PrintLE ( " DANGER SM: \n " , p - > obj . err . rpt , p - > D , p - > D , p - > sMM ) ;
}
if ( cmVOR_CholZ ( u , p - > D ) = = NULL )
{
return cmCtxRtCondition ( & p - > obj , cmSingularMtxRC , " A singular covariance matrix (Cholesky factorization failed.) was encountered in _cmGmmUpdateCovar ( ) . " ) ;
}
if ( p - > logDetV [ i ] = = 0 )
{
cmGmmPrint ( p , true ) ;
return cmCtxRtCondition ( & p - > obj , cmSingularMtxRC , " A singular covariance matrix (det==0) was encountered in _cmGmmUpdateCovar ( ) . " ) ;
}
if ( r = = NULL )
{
//cmCtxPrint(c,"%i\n",i);
//cmVOR_PrintLE("DANGER SM:\n",p->obj.err.rpt,p->D,p->D,p->sMM);
return cmCtxRtCondition ( & p - > obj , cmSingularMtxRC , " A singular covariance matrix (inversion failed) was encountered in _cmGmmUpdateCovar ( ) . " ) ;
}
}
return cmOkRC ;
}
cmRC_t cmGmmInit ( cmGmm_t * p , unsigned K , unsigned D , const cmReal_t * gV , const cmReal_t * uM , const cmReal_t * sMM , unsigned uflags )
{
cmRC_t rc ;
if ( ( rc = cmGmmFinal ( p ) ) ! = cmOkRC )
return rc ;
// gM[K] uM[DK] sMM[DDK] isMM[DDK]+ uMM[DDK] logDetV[K] t[DD] fact[K]
/*
unsigned n = K + ( D * K ) + ( D * D * K ) + ( D * D * K ) + ( D * D * K ) + K + ( D * D ) + K ;
p - > gV = cmArrayResizeZ ( c , & p - > memA , n , cmReal_t ) ;
p - > uM = p - > gV + K ;
p - > sMM = p - > uM + ( D * K ) ;
p - > isMM = p - > sMM + ( D * D * K ) ;
p - > uMM = p - > isMM + ( D * D * K ) ;
p - > logDetV = p - > uMM + ( D * D * K ) ;
p - > t = p - > logDetV + K ;
*/
//cmArrayResizeVZ(c, &p->memA, cmReal_t, &p->gV,K, &p->uM,D*K, &p->sMM,D*D*K,
//&p->isMM,D*D*K, &p->uMM,D*D*K, &p->logDetV,K, &p->t,D*D, NULL );
p - > gV = cmMemResizeZ ( cmReal_t , p - > gV , K ) ;
p - > uM = cmMemResizeZ ( cmReal_t , p - > uM , D * K ) ;
p - > sMM = cmMemResizeZ ( cmReal_t , p - > sMM , D * D * K ) ;
p - > isMM = cmMemResizeZ ( cmReal_t , p - > isMM , D * D * K ) ;
p - > uMM = cmMemResizeZ ( cmReal_t , p - > uMM , D * D * K ) ;
p - > logDetV = cmMemResizeZ ( cmReal_t , p - > logDetV , K ) ;
p - > t = cmMemResizeZ ( cmReal_t , p - > t , D * D ) ;
p - > K = K ;
p - > D = D ;
p - > uflags = uflags ;
if ( gV ! = NULL )
cmVOR_Copy ( p - > gV , K , gV ) ;
if ( uM ! = NULL )
cmVOR_Copy ( p - > uM , D * K , uM ) ;
return _cmGmmUpdateCovar ( p , sMM ) ;
}
cmRC_t cmGmmFinal ( cmGmm_t * p )
{ return cmOkRC ; }
typedef struct
{
cmGmm_t * p ;
const cmReal_t * xM ;
unsigned colCnt ;
} _cmGmmRdFuncData_t ;
const cmReal_t * _cmGmmReadFunc ( void * userPtr , unsigned colIdx )
{
assert ( colIdx < ( ( const _cmGmmRdFuncData_t * ) userPtr ) - > colCnt ) ;
return ( ( const _cmGmmRdFuncData_t * ) userPtr ) - > xM + ( colIdx * ( ( const _cmGmmRdFuncData_t * ) userPtr ) - > p - > D ) ;
}
// xM[D,xN]
// yV[xN]
// yM[xN,K]
cmRC_t cmGmmEval ( cmGmm_t * p , const cmReal_t * xM , unsigned xN , cmReal_t * yV , cmReal_t * yM )
{
_cmGmmRdFuncData_t r ;
r . colCnt = xN ;
r . p = p ;
r . xM = xM ;
return cmGmmEval2 ( p , _cmGmmReadFunc , & r , xN , yV , yM ) ;
}
cmRC_t cmGmmEval2 ( cmGmm_t * p , cmGmmReadFunc_t readFunc , void * userFuncPtr , unsigned xN , cmReal_t * yV , cmReal_t * yM )
{
cmReal_t tV [ xN ] ;
unsigned k ;
//cmVOR_PrintL("cV: ",p->obj.err.rpt, 1, p->K, p->gV);
//cmVOR_PrintL("uM:\n",p->obj.err.rpt, p->D, p->K, p->uM );
//
cmVOR_Fill ( yV , xN , 0 ) ;
// for each component PDF
for ( k = 0 ; k < p - > K ; k + + )
{
const cmReal_t * meanV = p - > uM + ( k * p - > D ) ;
const cmReal_t * isM = p - > isMM + ( k * p - > D * p - > D ) ;
cmReal_t * pV ;
if ( yM = = NULL )
pV = tV ;
else
pV = yM + ( k * xN ) ;
// evaluate the kth component PDF with xM[1:T]
//cmVOR_MultVarGaussPDF2( pV, xM, meanV, isM, p->logDetV[k], p->D, xN, cmIsFlag(p->uflags,cmGmmDiagFl) );
cmVOR_MultVarGaussPDF3 ( pV , readFunc , userFuncPtr , meanV , isM , p - > logDetV [ k ] , p - > D , xN , cmIsFlag ( p - > uflags , cmGmmDiagFl ) ) ;
// apply the kth component weight
cmVOR_MultVS ( pV , xN , p - > gV [ k ] ) ;
// sum the result into the output vector
cmVOR_AddVV ( yV , xN , pV ) ;
}
return cmOkRC ;
}
// Evaluate each component for a single data point
// xV[D] - observed data point
// yV[K] - output contains the evaluation for each component
cmRC_t cmGmmEval3 ( cmGmm_t * p , const cmReal_t * xV , cmReal_t * yV )
{
unsigned k ;
for ( k = 0 ; k < p - > K ; + + k )
{
const cmReal_t * meanV = p - > uM + ( k * p - > D ) ;
const cmReal_t * isM = p - > isMM + ( k * p - > D * p - > D ) ;
// evaluate the kth component PDF with xM[1:T]
cmVOR_MultVarGaussPDF2 ( yV + k , xV , meanV , isM , p - > logDetV [ k ] , p - > D , 1 , cmIsFlag ( p - > uflags , cmGmmDiagFl ) ) ;
// apply the kth component weight
yV [ k ] * = p - > gV [ k ] ;
}
return cmOkRC ;
}
cmReal_t _cmGmmKmeansDistFunc ( void * userPtr , const cmReal_t * v0 , const cmReal_t * v1 , unsigned vn )
{ return cmVOR_EuclidDistance ( v0 , v1 , vn ) ; }
cmRC_t cmGmmRandomize2 ( cmGmm_t * p , cmGmmReadFunc_t readFunc , void * funcUserPtr , unsigned xN , const cmReal_t * uM , const bool * roFlV )
{
unsigned k ;
unsigned iV [ p - > K ] ;
if ( uM = = NULL )
roFlV = NULL ;
// randomize the mixture coefficients
cmVOR_Random ( p - > gV , p - > K , 0.0 , 1.0 ) ;
cmVOR_NormalizeProbability ( p - > gV , p - > K ) ;
// fill iV with random integers between 0 and xN-1
cmVOU_Random ( iV , p - > K , xN - 1 ) ;
// for each component
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t r [ p - > D ] ;
// if this component's mean is not read-only
if ( roFlV = = NULL | | roFlV [ k ] = = false )
{
const cmReal_t * xV = NULL ;
if ( uM = = NULL )
xV = readFunc ( funcUserPtr , iV [ k ] ) ; // read a random frame index
else
xV = uM + ( k * p - > D ) ; // select a user supplied mean vector
assert ( xV ! = NULL ) ;
// set the random feature vector as this components mean value
cmVOR_Copy ( p - > uM + ( k * p - > D ) , p - > D , xV ) ;
}
cmReal_t * sM = p - > sMM + ( k * p - > D * p - > D ) ;
// create a random covariance mtx
if ( cmIsFlag ( p - > uflags , cmGmmDiagFl ) )
{
// create a random diag. covar mtx
cmVOR_Random ( r , p - > D , 0.0 , 1.0 ) ;
cmVOR_Diag ( sM , p - > D , r ) ;
}
else
{
// create a random symetric positive definite matrix
cmVOR_RandSymPosDef ( sM , p - > D , p - > t ) ;
}
}
unsigned * classIdxV = cmMemAllocZ ( unsigned , xN ) ;
// if some components have read-only mean's
if ( uM ! = NULL & & roFlV ! = NULL )
{
assert ( xN > = p - > K ) ;
for ( k = 0 ; k < p - > K ; + + k )
classIdxV [ k ] = roFlV [ k ] ;
}
// use kmeans clustering to move the means closer to their center values
if ( cmIsFlag ( p - > uflags , cmGmmSkipKmeansFl ) = = false )
cmVOR_Kmeans2 ( classIdxV , p - > uM , p - > K , readFunc , p - > D , xN , funcUserPtr , _cmGmmKmeansDistFunc , NULL , - 1 , 0 ) ;
cmMemPtrFree ( & classIdxV ) ;
return _cmGmmUpdateCovar ( p , p - > sMM ) ;
}
cmRC_t cmGmmRandomize ( cmGmm_t * p , const cmReal_t * xM , unsigned xN )
{
_cmGmmRdFuncData_t r ;
r . colCnt = xN ;
r . p = p ;
r . xM = xM ;
return cmGmmRandomize2 ( p , _cmGmmReadFunc , & r , xN , NULL , NULL ) ;
}
// xM[D,xN]
cmRC_t cmGmmTrain ( cmGmm_t * p , const cmReal_t * xM , unsigned xN , unsigned * iterCntPtr )
{
unsigned i , k ;
cmRC_t rc ;
if ( ( rc = cmGmmRandomize ( p , xM , xN ) ) ! = cmOkRC )
return rc ;
//cmGmmPrint(c,p);
// wM[xN,K]
cmReal_t wM [ xN * p - > K ] ; // wM[N,K] soft assignment mtx
unsigned wV [ xN ] ; // wV[N] hard assignment vector
unsigned stopCnt = 0 ;
unsigned curStopCnt = 0 ;
if ( iterCntPtr ! = NULL )
{
stopCnt = * iterCntPtr ;
* iterCntPtr = 0 ;
}
else
{
// BUG BUG BUG
// stopCnt is used uninitialized when iterCntPtr == NULL
assert ( 0 ) ;
}
while ( 1 )
{
//cmVOR_NormalizeProbability(p->gV,p->K);
cmCtxPrint ( p - > obj . ctx , " iter:%i -------------------------------------------- \n " , * iterCntPtr ) ;
cmVOR_PrintL ( " uM: \n " , p - > obj . err . rpt , p - > D , p - > K , p - > uM ) ;
cmVOR_PrintL ( " gV: \n " , p - > obj . err . rpt , 1 , p - > K , p - > gV ) ;
//cmGmmPrint(c,p);
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t * wp = wM + ( k * xN ) ;
// calc the prob that each data point in xM[] was generated by the kth gaussian
// and store as a column vector in wM[:,k]
cmVOR_MultVarGaussPDF2 ( wp , xM , p - > uM + ( k * p - > D ) , p - > isMM + ( k * p - > D * p - > D ) , p - > logDetV [ k ] , p - > D , xN , cmIsFlag ( p - > uflags , cmGmmDiagFl ) ) ;
// scale the prob by the gain coeff for gaussian k
cmVOR_MultVS ( wp , xN , p - > gV [ k ] ) ;
}
//cmVOR_PrintL("wM:\n",p->obj.err.rpt,xN,p->K,wM);
bool doneFl = true ;
for ( i = 0 ; i < xN ; + + i )
{
// form a probability for the ith data point weights
cmVOR_NormalizeProbabilityN ( wM + i , p - > K , xN ) ;
// select the cluster to which the ith data point is most likely to belong
unsigned mi = cmVOR_MaxIndex ( wM + i , p - > K , xN ) ;
// if the ith data point changed clusters
if ( mi ! = wV [ i ] )
{
doneFl = false ;
wV [ i ] = mi ;
}
}
curStopCnt = doneFl ? curStopCnt + 1 : 0 ;
// if no data points changed owners then the clustering is complete
if ( curStopCnt = = stopCnt )
{
//cmVOU_PrintL("wV: ",p->obj.err.rpt,xN,1,wV);
break ;
}
// for each cluster
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t * uV = p - > uM + ( k * p - > D ) ; // meanV[k]
cmReal_t * sM = p - > sMM + ( k * p - > D * p - > D ) ; // covarM[k]
cmReal_t sw = cmVOR_Sum ( wM + ( k * xN ) , xN ) ;
// update the kth weight
p - > gV [ k ] = sw / xN ;
// form a sum of all data points weighted by their soft assignment to cluster k
cmReal_t sumV [ p - > D ] ;
cmVOR_MultVMV ( sumV , p - > D , xM , xN , wM + k * xN ) ;
// update the mean[k]
cmVOR_DivVVS ( uV , p - > D , sumV , sw ) ;
// update the covar[k]
// sM += ( W(i,k) .* ((X(:,i) - uV) * (X(:,i) - uV)'));
cmVOR_Fill ( sM , p - > D * p - > D , 0 ) ;
for ( i = 0 ; i < xN ; + + i )
{
cmReal_t duV [ p - > D ] ;
cmVOR_SubVVV ( duV , p - > D , xM + ( i * p - > D ) , uV ) ; // duV[] = xM[:,i] - uV[];
cmVOR_MultMMM ( p - > t , p - > D , p - > D , duV , duV , 1 ) ; // t[,] = duV[] * duV[]'
cmVOR_MultVS ( p - > t , p - > D * p - > D , wM [ k * xN + i ] ) ; // t[,] *= wM[i,k]
cmVOR_AddVV ( sM , p - > D * p - > D , p - > t ) ; // sM[,] += t[,];
}
cmVOR_DivVS ( sM , p - > D * p - > D , sw ) ; // sM[,] ./ sw;
}
// update the inverted covar mtx and covar det.
if ( ( rc = _cmGmmUpdateCovar ( p , p - > sMM ) ) ! = cmOkRC )
return rc ;
if ( iterCntPtr ! = NULL )
* iterCntPtr + = 1 ;
}
return cmOkRC ;
}
// xM[D,xN]
cmRC_t cmGmmTrain2 ( cmGmm_t * p , cmGmmReadFunc_t readFunc , void * userFuncPtr , unsigned xN , unsigned * iterCntPtr , const cmReal_t * uM , const bool * roFlV , int maxIterCnt )
{
unsigned i , j , k ;
cmRC_t rc ;
// if uM[] is not set then ignore roFlV[]
if ( uM = = NULL )
roFlV = NULL ;
if ( ( rc = cmGmmRandomize2 ( p , readFunc , userFuncPtr , xN , uM , roFlV ) ) ! = cmOkRC )
return rc ;
//cmGmmPrint(c,p);
// wM[xN,K] soft assignment mtx
cmReal_t * wM = cmMemAlloc ( cmReal_t , xN * p - > K ) ;
// wV[N] hard assignment vector
unsigned * wV = cmMemAlloc ( unsigned , xN ) ;
unsigned stopCnt = 0 ;
unsigned curStopCnt = 0 ;
if ( iterCntPtr ! = NULL )
{
stopCnt = * iterCntPtr ;
* iterCntPtr = 0 ;
}
else
{
// BUG BUG BUG
// stopCnt is used uninitialized when iterCntPtr == NULL
assert ( 0 ) ;
}
while ( 1 )
{
//cmCtxPrint(p->obj.ctx,"iter:%i --------------------------------------------\n",*iterCntPtr );
//cmVOR_PrintL("uM:\n", p->obj.err.rpt, p->D, p->K, p->uM );
cmVOR_PrintL ( " gV: \n " , p - > obj . err . rpt , 1 , p - > K , p - > gV ) ;
//cmGmmPrint(c,p);
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t * wp = wM + ( k * xN ) ;
// calc the prob that each data point in xM[] was generated by the kth gaussian
// and store as a column vector in wM[:,k]
cmVOR_MultVarGaussPDF3 ( wp , readFunc , userFuncPtr , p - > uM + ( k * p - > D ) , p - > isMM + ( k * p - > D * p - > D ) , p - > logDetV [ k ] , p - > D , xN , cmIsFlag ( p - > uflags , cmGmmDiagFl ) ) ;
// scale the prob by the gain coeff for gaussian k
cmVOR_MultVS ( wp , xN , p - > gV [ k ] ) ;
}
//cmVOR_PrintL("wM:\n",p->obj.err.rpt,xN,p->K,wM);
bool doneFl = true ;
unsigned changeCnt = 0 ;
for ( i = 0 ; i < xN ; + + i )
{
// form a probability for the ith data point weights
cmVOR_NormalizeProbabilityN ( wM + i , p - > K , xN ) ;
// select the cluster to which the ith data point is most likely to belong
unsigned mi = cmVOR_MaxIndex ( wM + i , p - > K , xN ) ;
// if the ith data point changed clusters
if ( mi ! = wV [ i ] )
{
+ + changeCnt ;
doneFl = false ;
wV [ i ] = mi ;
}
}
curStopCnt = doneFl ? curStopCnt + 1 : 0 ;
printf ( " %i stopCnt:%i changeCnt:%i \n " , * iterCntPtr , curStopCnt , changeCnt ) ;
// if no data points changed owners then the clustering is complete
if ( curStopCnt = = stopCnt )
{
//cmVOU_PrintL("wV: ",p->obj.err.rpt,xN,1,wV);
break ;
}
// if a maxIterCnt was given and the cur iter cnt exceeds the max iter cnt then stop
if ( maxIterCnt > = 1 & & * iterCntPtr > = maxIterCnt )
break ;
// form a sum of all data points weighted by their soft assignment to cluster k
// NOTE: cmGmmTrain() performs this step more efficiently because it use
// an LAPACK matrix multiply.
cmReal_t sumM [ p - > D * p - > K ] ;
cmVOR_Zero ( sumM , p - > D * p - > K ) ;
for ( i = 0 ; i < xN ; + + i )
{
const cmReal_t * xV = readFunc ( userFuncPtr , i ) ;
assert ( xV ! = NULL ) ;
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t weight = wM [ i + ( k * xN ) ] ;
for ( j = 0 ; j < p - > D ; + + j )
sumM [ j + ( k * p - > D ) ] + = xV [ j ] * weight ;
}
}
// for each cluster that is not marked as read-only
for ( k = 0 ; k < p - > K ; + + k )
{
cmReal_t * uV = p - > uM + ( k * p - > D ) ; // meanV[k]
cmReal_t * sM = p - > sMM + ( k * p - > D * p - > D ) ; // covarM[k]
cmReal_t sw = cmVOR_Sum ( wM + ( k * xN ) , xN ) ;
// update the kth weight
p - > gV [ k ] = sw / xN ;
// if this component's mean is not read-only
if ( ( roFlV = = NULL | | roFlV [ k ] = = false ) & & sw ! = 0 )
{
// get vector of all data points weighted by their soft assignment to cluster k
cmReal_t * sumV = sumM + ( k * p - > D ) ; // sumV[p->D];
// update the mean[k]
cmVOR_DivVVS ( uV , p - > D , sumV , sw ) ;
}
// update the covar[k]
// sM += ( W(i,k) .* ((X(:,i) - uV) * (X(:,i) - uV)'));
cmVOR_Fill ( sM , p - > D * p - > D , 0 ) ;
for ( i = 0 ; i < xN ; + + i )
{
cmReal_t duV [ p - > D ] ;
const cmReal_t * xV = readFunc ( userFuncPtr , i ) ;
assert ( xV ! = NULL ) ;
cmVOR_SubVVV ( duV , p - > D , xV , uV ) ; // duV[] = xM[:,i] - uV[];
cmVOR_MultMMM ( p - > t , p - > D , p - > D , duV , duV , 1 ) ; // t[,] = duV[] * duV[]'
cmVOR_MultVS ( p - > t , p - > D * p - > D , wM [ k * xN + i ] ) ; // t[,] *= wM[i,k]
cmVOR_AddVV ( sM , p - > D * p - > D , p - > t ) ; // sM[,] += t[,];
}
if ( sw ! = 0 )
cmVOR_DivVS ( sM , p - > D * p - > D , sw ) ; // sM[,] ./ sw;
}
// update the inverted covar mtx and covar det.
if ( ( rc = _cmGmmUpdateCovar ( p , p - > sMM ) ) ! = cmOkRC )
goto errLabel ;
if ( iterCntPtr ! = NULL )
* iterCntPtr + = 1 ;
}
cmMemPtrFree ( & wM ) ;
cmMemPtrFree ( & wV ) ;
errLabel :
return cmOkRC ;
}
cmRC_t cmGmmTrain3 ( cmGmm_t * p , const cmReal_t * xM , unsigned xN , unsigned * iterCntPtr )
{
_cmGmmRdFuncData_t r ;
r . colCnt = xN ;
r . p = p ;
r . xM = xM ;
return cmGmmTrain2 ( p , _cmGmmReadFunc , & r , xN , iterCntPtr , NULL , NULL , - 1 ) ;
}
cmRC_t cmGmmGenerate ( cmGmm_t * p , cmReal_t * yM , unsigned yN )
{
unsigned i = 0 ;
unsigned kV [ yN ] ;
// use weighted random selection to choose the component for each output value
cmVOR_WeightedRandInt ( kV , yN , p - > gV , p - > K ) ;
// cmVOU_Print(p->obj.err.rpt,1,yN,kV);
for ( i = 0 ; i < yN ; + + i )
{
const cmReal_t * uV = p - > uM + ( kV [ i ] * p - > D ) ;
unsigned idx = kV [ i ] * p - > D * p - > D ;
//cmVOR_PrintL("sM\n",p->obj.err.rpt,p->D,p->D,sM);
if ( cmIsFlag ( p - > uflags , cmGmmDiagFl ) )
{
const cmReal_t * sM = p - > sMM + idx ;
cmVOR_RandomGaussDiagM ( yM + ( i * p - > D ) , p - > D , 1 , uV , sM ) ;
}
else
{
const cmReal_t * uM = p - > uMM + idx ;
cmVOR_RandomGaussNonDiagM2 ( yM + ( i * p - > D ) , p - > D , 1 , uV , uM ) ;
}
}
return cmOkRC ;
}
void cmGmmPrint ( cmGmm_t * p , bool fl )
{
unsigned k ;
//cmCtx* c = p->obj.ctx;
cmVOR_PrintL ( " gV: " , p - > obj . err . rpt , 1 , p - > K , p - > gV ) ;
cmVOR_PrintL ( " mM: \n " , p - > obj . err . rpt , p - > D , p - > K , p - > uM ) ;
for ( k = 0 ; k < p - > K ; + + k )
cmVOR_PrintL ( " sM: \n " , p - > obj . err . rpt , p - > D , p - > D , p - > sMM + ( k * p - > D * p - > D ) ) ;
if ( fl )
{
for ( k = 0 ; k < p - > K ; + + k )
cmVOR_PrintL ( " isM: \n " , p - > obj . err . rpt , p - > D , p - > D , p - > isMM + ( k * p - > D * p - > D ) ) ;
for ( k = 0 ; k < p - > K ; + + k )
cmVOR_PrintL ( " uM: \n " , p - > obj . err . rpt , p - > D , p - > D , p - > uMM + ( k * p - > D * p - > D ) ) ;
cmVOR_PrintL ( " logDetV: \n " , p - > obj . err . rpt , 1 , p - > K , p - > logDetV ) ;
}
}
void cmGmmTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
cmCtx * c = cmCtxAlloc ( NULL , rpt , lhH , stH ) ;
unsigned K = 2 ;
unsigned D = 2 ;
cmReal_t gV [ 2 ] = { .5 , .5 } ;
cmReal_t uM [ 4 ] = { .3 , .3 , .8 , .8 } ;
cmReal_t sMM [ 8 ] = { .1 , 0 , 0 , .1 , .1 , 0 , 0 , .1 } ;
unsigned flags = cmGmmDiagFl ;
unsigned M = 100 ;
cmReal_t xM [ D * M ] ;
cmReal_t yV [ M ] ;
unsigned i , j ;
cmPlotSetup ( " MultDimGauss Test " , 1 , 1 ) ;
cmGmm_t * p = cmGmmAlloc ( c , NULL , K , D , gV , uM , sMM , flags ) ;
if ( 0 )
{
cmGmmPrint ( p , true ) ;
for ( i = 0 ; i < 10 ; i + + )
for ( j = 0 ; j < 20 ; j + = 2 )
{
xM [ ( i * 20 ) + j ] = .1 * i ; ;
xM [ ( i * 20 ) + j + 1 ] = .1 * ( j / 2 ) ; ;
}
// octave equivalent
// x0= .1 * ones(1,10);
// x = [ 0*x0 1*x0 2*x0 3*x0 4*x0 5*x0 6*x0 7*x0 8*x0 9*x0];
// x = [x; repmat([0:.1:1],1,10)];
// y = mvnpdf(x',[.3 .3],[.1 0; 0 .1]); plot(y);
cmGmmEval ( p , xM , M , yV , NULL ) ;
//cmVOR_PrintL( "xM\n", rpt, D, M, xM );
cmVOR_PrintL ( " yV \n " , rpt , 10 , 10 , yV ) ;
//printf("y:%f\n",yV[0]);
cmPlotLineD ( NULL , NULL , yV , NULL , M , NULL , kSolidPlotLineId ) ;
}
if ( 0 )
{
cmReal_t yM [ D * M ] ;
cmReal_t yMt [ M * D ] ;
cmReal_t uMt [ p - > K * D ] ;
unsigned iterCnt = 10 ;
//srand( time(NULL) );
cmGmmGenerate ( p , yM , M ) ;
p - > uflags = 0 ; // turn off diagonal condition
if ( cmGmmTrain3 ( p , yM , M , & iterCnt ) ! = cmOkRC )
return ;
cmCtxPrint ( c , " iterCnt:%i \n " , iterCnt ) ;
cmGmmPrint ( p , true ) ;
cmVOR_Transpose ( yMt , yM , D , M ) ;
//cmVOR_PrintL("yMt\n",vReportFunc,M,D,yMt);
cmPlotLineD ( NULL , yMt , yMt + M , NULL , M , " blue " , kAsteriskPlotPtId ) ;
cmVOR_Transpose ( uMt , p - > uM , D , p - > K ) ;
cmVOR_PrintL ( " uMt: \n " , p - > obj . err . rpt , p - > K , p - > D , uMt ) ;
cmPlotLineD ( NULL , uMt , uMt + p - > K , NULL , p - > D , " red " , kXPlotPtId ) ;
}
if ( 1 )
{
cmGmmFree ( & p ) ;
cmReal_t cV0 [ ] = { .7 , .3 } ;
cmReal_t uM0 [ ] = { .2 , .1 , .1 , .2 } ;
cmReal_t sMM0 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
unsigned flags = 0 ;
K = 2 ;
D = 2 ;
cmGmm_t * p = cmGmmAlloc ( c , NULL , K , D , cV0 , uM0 , sMM0 , flags ) ;
xM [ 0 ] = 0.117228 ;
xM [ 1 ] = 0.110079 ;
cmGmmEval ( p , xM , 1 , yV , NULL ) ;
cmCtxPrint ( c , " y: %f \n " , yV [ 0 ] ) ;
}
cmPlotDraw ( ) ;
cmGmmFree ( & p ) ;
cmCtxFree ( & c ) ;
}
//------------------------------------------------------------------------------------------------------------
cmChmm_t * cmChmmAlloc ( cmCtx * c , cmChmm_t * ap , unsigned stateN , unsigned mixN , unsigned dimN , const cmReal_t * iV , const cmReal_t * aM )
{
cmChmm_t * p = cmObjAlloc ( cmChmm_t , c , ap ) ;
if ( stateN > 0 & & dimN > 0 )
if ( cmChmmInit ( p , stateN , mixN , dimN , iV , aM ) ! = cmOkRC )
cmChmmFree ( & p ) ;
return p ;
}
cmRC_t cmChmmFree ( cmChmm_t * * pp )
{
cmRC_t rc = cmOkRC ;
cmChmm_t * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmChmmFinal ( p ) ) ! = cmOkRC )
return rc ;
cmMemPtrFree ( & p - > iV ) ;
cmMemPtrFree ( & p - > aM ) ;
cmMemPtrFree ( & p - > bV ) ;
cmMemPtrFree ( & p - > bM ) ;
cmObjFree ( pp ) ;
return cmOkRC ;
}
cmRC_t cmChmmInit ( cmChmm_t * p , unsigned stateN , unsigned mixN , unsigned dimN , const cmReal_t * iV , const cmReal_t * aM )
{
cmRC_t rc ;
unsigned i ;
if ( ( rc = cmChmmFinal ( p ) ) ! = cmOkRC )
return rc ;
// iV[] aM
/*
unsigned n = stateN + ( stateN * stateN ) ;
p - > iV = cmArrayResizeZ ( c , & p - > memA , n , cmReal_t ) ;
p - > aM = p - > iV + stateN ;
*/
//cmArrayResizeVZ(c,&p->memA, cmReal_t, &p->iV,stateN, &p->aM, stateN*stateN, NULL );
p - > iV = cmMemResizeZ ( cmReal_t , p - > iV , stateN ) ;
p - > aM = cmMemResizeZ ( cmReal_t , p - > aM , stateN * stateN ) ;
p - > bV = cmMemResizeZ ( cmGmm_t * , p - > bV , stateN ) ;
p - > N = stateN ;
p - > K = mixN ;
p - > D = dimN ;
if ( iV ! = NULL )
cmVOR_Copy ( p - > iV , p - > N , iV ) ;
if ( aM ! = NULL )
cmVOR_Copy ( p - > aM , p - > N * p - > N , aM ) ;
for ( i = 0 ; i < p - > N ; + + i )
p - > bV [ i ] = cmGmmAlloc ( p - > obj . ctx , NULL , p - > K , p - > D , NULL , NULL , NULL , 0 ) ;
//p->mfp = cmCtxAllocDebugFile( p->obj.ctx,"chmm");
return cmOkRC ;
}
cmRC_t cmChmmFinal ( cmChmm_t * p )
{
if ( p ! = NULL )
{
unsigned i ;
for ( i = 0 ; i < p - > N ; + + i )
cmGmmFree ( & p - > bV [ i ] ) ;
cmMemPtrFree ( & p - > bM ) ;
//if( p->mfp != NULL )
// cmCtxFreeDebugFile(p->obj.ctx,&p->mfp);
}
return cmOkRC ;
}
cmRC_t cmChmmRandomize ( cmChmm_t * p , const cmReal_t * oM , unsigned T )
{
cmRC_t rc ;
unsigned i ;
unsigned N = p - > N ;
// randomize the initial state probabilities
cmVOR_Random ( p - > iV , N , 0.0 , 1.0 ) ;
cmVOR_NormalizeProbability ( p - > iV , N ) ;
// randomize the state transition matrix
cmVOR_Random ( p - > aM , N * N , 0.0 , 1.0 ) ;
for ( i = 0 ; i < N ; + + i )
{
cmVOR_NormalizeProbabilityN ( p - > aM + i , N , N ) ; // rows of aM must sum to 1.0
if ( ( rc = cmGmmRandomize ( p - > bV [ i ] , oM , T ) ) ! = cmOkRC ) // randomize the GMM assoc'd with state i
return rc ;
}
cmMemPtrFree ( & p - > bM ) ; // force bM[] to be recalculated
return cmOkRC ;
}
cmReal_t _cmChmmKmeansDist ( void * userPtr , const cmReal_t * v0 , const cmReal_t * v1 , unsigned vn )
{ return cmVOR_EuclidDistance ( v0 , v1 , vn ) ; }
cmRC_t cmChmmSegKMeans ( cmChmm_t * p , const cmReal_t * oM , unsigned T , cmReal_t threshProb , unsigned maxIterCnt , unsigned iterCnt )
{
cmCtx * c = p - > obj . ctx ;
cmRC_t rc = cmOkRC ;
unsigned i , j , k , t ;
unsigned N = p - > N ;
unsigned K = p - > K ;
unsigned D = p - > D ;
//unsigned qV[T];
//cmReal_t alphaM[N*T];
//unsigned clusterIdxV[T];
//cmReal_t centroidM[D*N];
/*
unsigned sz = 2 * ALIGN_B ( T , unsigned ) +
ALIGN_B ( N * T , cmReal_t ) +
ALIGN_B ( D * N , cmReal_t ) ;
cmArray mem ;
cmArrayAlloc ( c , & mem ) ;
unsigned * qV = ( unsigned * ) cmArrayResize ( c , & mem , sz , char ) ;
cmReal_t * alphaM = ( cmReal_t * ) ( qV + ALIGN_T ( T , unsigned ) ) ;
unsigned * clusterIdxV = ( unsigned * ) ( alphaM + ALIGN_T ( N * T , cmReal_t ) ) ;
cmReal_t * centroidM = ( cmReal_t * ) ( clusterIdxV + ALIGN_T ( T , unsigned ) ) ;
*/
unsigned * qV = cmMemAlloc ( unsigned , T ) ;
cmReal_t * alphaM = cmMemAlloc ( cmReal_t , N * T ) ;
unsigned * clusterIdxV = cmMemAlloc ( unsigned , T ) ;
cmReal_t * centroidM = cmMemAlloc ( cmReal_t , D * N ) ;
cmReal_t logPr = 0 ;
bool reportFl = true ;
cmChmmRandomize ( p , oM , T ) ;
// cluster the observations into N groups
cmVOR_Kmeans ( qV , centroidM , N , oM , D , T , NULL , 0 , false , _cmChmmKmeansDist , NULL ) ;
for ( i = 0 ; i < maxIterCnt ; + + i )
{
unsigned jnV [ N ] ;
if ( reportFl )
cmCtxPrint ( c , " SegKM: ----------------------------------------------------%i \n " , i ) ;
// get the count of data points in each state
cmVOU_Fill ( jnV , N , 0 ) ;
for ( t = 0 ; t < T ; + + t )
+ + jnV [ qV [ t ] ] ;
// for each state
for ( j = 0 ; j < N ; + + j )
{
cmGmm_t * g = p - > bV [ j ] ;
// cluster all datapoints which were assigned to state j
cmVOR_Kmeans ( clusterIdxV , g - > uM , K , oM , D , T , qV , j , false , _cmChmmKmeansDist , NULL ) ;
// for each cluster
for ( k = 0 ; k < K ; + + k )
{
unsigned kN = 0 ;
// kN is count of data points assigned to cluster k
for ( t = 0 ; t < T ; + + t )
if ( clusterIdxV [ t ] = = k )
+ + kN ;
g - > gV [ k ] = ( cmReal_t ) kN / jnV [ j ] ;
// the covar of the kth component is the sample covar of cluster k
cmVOR_GaussCovariance ( g - > sMM + ( k * D * D ) , D , oM , T , g - > uM + ( k * D ) , clusterIdxV , k ) ;
}
if ( ( rc = _cmGmmUpdateCovar ( g , g - > sMM ) ) ! = cmOkRC )
goto errLabel ;
}
if ( i = = 0 )
{
// count transitions from i to j
for ( t = 0 ; t < T - 1 ; + + t )
p - > aM [ ( qV [ t + 1 ] * N ) + qV [ t ] ] + = 1.0 ;
for ( j = 0 ; j < N ; + + j )
{
// normalize state transitions by dividing by times in each state
for ( k = 0 ; k < N ; k + + )
p - > aM [ ( k * N ) + j ] / = jnV [ j ] ;
cmVOR_NormalizeProbabilityN ( p - > aM + j , N , N ) ;
cmGmmEval ( p - > bV [ j ] , oM , 1 , p - > iV + j , NULL ) ;
}
}
if ( ( rc = cmChmmTrain ( p , oM , T , iterCnt , 0 , 0 ) ) ! = cmOkRC )
goto errLabel ;
// calculate the prob. that the new model generated the data
cmReal_t logPr0 = cmChmmForward ( p , oM , T , alphaM , NULL ) ;
cmReal_t dLogPr = logPr0 - logPr ;
if ( reportFl )
cmCtxPrint ( c , " pr:%f d:%f \n " , logPr0 , dLogPr ) ;
if ( ( dLogPr > 0 ) & & ( dLogPr < threshProb ) )
break ;
logPr = logPr0 ;
// fill qV[] with the state at each time t
cmChmmDecode ( p , oM , T , qV ) ;
}
errLabel :
cmMemPtrFree ( & qV ) ;
cmMemPtrFree ( & alphaM ) ;
cmMemPtrFree ( & clusterIdxV ) ;
cmMemPtrFree ( & centroidM ) ;
return rc ;
}
cmRC_t cmChmmSetGmm ( cmChmm_t * p , unsigned i , const cmReal_t * wV , const cmReal_t * uM , const cmReal_t * sMM , unsigned flags )
{
assert ( i < p - > N ) ;
cmMemPtrFree ( & p - > bM ) ; // force bM[] to be recalculated
return cmGmmInit ( p - > bV [ i ] , p - > K , p - > D , wV , uM , sMM , flags ) ;
}
// Return the probability of the observation for each state.
// oV[D] - multi-dim. observation data point
// pV[N] - probability of this observation for each state
void cmChmmObsProb ( const cmChmm_t * p , const cmReal_t * oV , cmReal_t * prV )
{
unsigned i ;
for ( i = 0 ; i < p - > N ; + + i )
cmGmmEval ( p - > bV [ i ] , oV , 1 , prV + i , NULL ) ;
}
// oM[D,T] - observation matrix
// alphaM[N,T] - prob of being in each state and observtin oM(:,t)
// bM[N,T] - (optional) state-observation probability matrix
// logPrV[T] - (optional) record the log prob of the data given the model at each time step
// Returns sum(logPrV[T])
cmReal_t cmChmmForward ( const cmChmm_t * p , const cmReal_t * oM , unsigned T , cmReal_t * alphaM , cmReal_t * logPrV )
{
unsigned t ;
cmReal_t logPr = 0 ;
// calc the prob of starting in each state
if ( p - > bM = = NULL )
cmChmmObsProb ( p , oM , alphaM ) ;
else
cmVOR_Copy ( alphaM , p - > N * T , p - > bM ) ;
cmVOR_MultVV ( alphaM , p - > N , p - > iV ) ;
cmReal_t s = cmVOR_Sum ( alphaM , p - > N ) ;
cmVOR_DivVS ( alphaM , p - > N , s ) ;
//cmVOR_PrintL("alpha:\n",p->obj.err.rpt,p->N,1,alphaM);
for ( t = 1 ; t < T ; + + t )
{
cmReal_t tmp [ p - > N ] ;
cmReal_t * alphaV = alphaM + t * p - > N ;
// calc the prob of the observation for each state
if ( p - > bM = = NULL )
cmChmmObsProb ( p , oM + ( t * p - > D ) , alphaV ) ;
// calc. the prob. of transitioning to each state at time t, from each state at t-1
cmVOR_MultVVM ( tmp , p - > N , alphaM + ( ( t - 1 ) * p - > N ) , p - > N , p - > aM ) ;
// calc the joint prob of transitioning from each state to each state and observing O(t).
cmVOR_MultVV ( alphaV , p - > N , tmp ) ;
// scale the probabilities to prevent underflow
s = cmVOR_Sum ( alphaV , p - > N ) ;
cmVOR_DivVS ( alphaV , p - > N , s ) ;
// track the log prob. of the model having generated the data up to time t.
cmReal_t pr = log ( s ) ;
if ( logPrV ! = NULL )
logPrV [ t ] = pr ;
logPr + = pr ;
}
return logPr ;
}
// oM[D,T]
// betaM[N,T]
void cmChmmBackward ( const cmChmm_t * p , const cmReal_t * oM , unsigned T , cmReal_t * betaM )
{
cmVOR_Fill ( betaM , p - > N * T , 1.0 ) ;
assert ( T > = 2 ) ;
int t = ( int ) T - 2 ;
for ( ; t > = 0 ; - - t )
{
cmReal_t tmp [ p - > N ] ;
if ( p - > bM = = NULL )
cmChmmObsProb ( p , oM + ( ( t + 1 ) * p - > D ) , tmp ) ;
else
cmVOR_Copy ( tmp , p - > N , p - > bM + ( ( t + 1 ) * p - > N ) ) ;
cmVOR_MultVV ( tmp , p - > N , betaM + ( ( t + 1 ) * p - > N ) ) ;
cmVOR_MultVMV ( betaM + ( t * p - > N ) , p - > N , p - > aM , p - > N , tmp ) ;
cmVOR_NormalizeProbability ( betaM + ( t * p - > N ) , p - > N ) ;
}
}
cmReal_t cmChmmCompare ( const cmChmm_t * p0 , const cmChmm_t * p1 , unsigned T )
{
assert ( p0 - > D = = p1 - > D ) ;
assert ( p0 - > N = = p1 - > N ) ;
cmReal_t oM [ p0 - > D * T ] ;
cmReal_t alphaM [ p0 - > N * T ] ;
cmChmmGenerate ( p0 , oM , T , NULL ) ;
cmReal_t logPr00 = cmChmmForward ( p0 , oM , T , alphaM , NULL ) ;
cmReal_t logPr01 = cmChmmForward ( p1 , oM , T , alphaM , NULL ) ;
cmChmmGenerate ( p1 , oM , T , NULL ) ;
cmReal_t logPr10 = cmChmmForward ( p0 , oM , T , alphaM , NULL ) ;
cmReal_t logPr11 = cmChmmForward ( p1 , oM , T , alphaM , NULL ) ;
cmReal_t d0 = ( logPr01 - logPr00 ) / T ;
cmReal_t d1 = ( logPr10 - logPr11 ) / T ;
return ( d0 + d1 ) / 2 ;
}
cmRC_t cmChmmGenerate ( const cmChmm_t * p , cmReal_t * oM , unsigned T , unsigned * sV )
{
unsigned i , si ;
// use weighted random selection to choose an intitial state
cmVOR_WeightedRandInt ( & si , 1 , p - > iV , p - > N ) ;
for ( i = 0 ; i < T ; + + i )
{
if ( sV ! = NULL )
sV [ i ] = si ;
// generate a random value using the GMM assoc'd with the current state
cmGmmGenerate ( p - > bV [ si ] , oM + ( i * p - > D ) , 1 ) ;
// choose the next state using the transition weights from the current state
cmVOR_WeightedRandInt ( & si , 1 , p - > aM + ( si * p - > N ) , p - > N ) ;
}
return cmOkRC ;
}
cmRC_t cmChmmDecode ( cmChmm_t * p , const cmReal_t * oM , unsigned T , unsigned * yV )
{
int i , j , t ;
unsigned N = p - > N ;
//unsigned psiM[N*T];
//cmReal_t delta[N];
/*
unsigned sz = ALIGN_B ( N * T , unsigned ) + ALIGN_B ( N , cmReal_t ) ;
cmArray mem ;
cmArrayAlloc ( c , & mem ) ;
unsigned * psiM = ( unsigned * ) cmArrayResize ( c , & mem , sz , char ) ;
cmReal_t * delta = ( cmReal_t * ) ( psiM + ALIGN_T ( N * T , unsigned ) ) ;
*/
unsigned * psiM = cmMemAlloc ( unsigned , N * T ) ;
cmReal_t * delta = cmMemAlloc ( cmReal_t , N ) ;
// get the prob of starting in each state
if ( p - > bM = = NULL )
cmChmmObsProb ( p , oM , delta ) ;
else
cmVOR_Copy ( delta , N , p - > bM ) ;
cmVOR_MultVV ( delta , p - > N , p - > iV ) ;
cmVOR_NormalizeProbability ( delta , p - > N ) ;
for ( t = 1 ; t < T ; + + t )
{
cmReal_t mV [ N ] ;
const cmReal_t * ap = p - > aM ;
// calc. the most likely new state given the most likely prev state
// and the transition matrix
for ( i = 0 ; i < N ; + + i )
{
const cmReal_t * dp = delta ;
unsigned psiIdx = t * N + i ;
mV [ i ] = * ap + + * * dp + + ;
psiM [ psiIdx ] = 0 ;
// find max value of: delta .* A(:,i)
for ( j = 1 ; j < N ; + + j )
{
cmReal_t v = * ap + + * * dp + + ;
if ( v > mV [ i ] )
{
mV [ i ] = v ;
psiM [ psiIdx ] = j ;
}
}
}
// mV[] now holds the prob. of the max likelihood state at time t
// for each possible state at t-1
// psiM[:,t] holds the index of the max likelihood state
// condition the most likely new state on the observations
if ( p - > bM = = NULL )
cmChmmObsProb ( p , oM + ( t * p - > D ) , delta ) ;
else
cmVOR_Copy ( delta , N , p - > bM + ( t * p - > N ) ) ;
cmVOR_MultVV ( delta , N , mV ) ; // condition it on the max. like current states
cmVOR_NormalizeProbability ( delta , N ) ; // normalize the prob.
}
// unwind psiM[] to form the max. likelihood state sequence
yV [ T - 1 ] = cmVOR_MaxIndex ( delta , N , 1 ) ;
for ( t = T - 2 ; t > = 0 ; - - t )
yV [ t ] = psiM [ ( ( t + 1 ) * N ) + yV [ t + 1 ] ] ;
cmMemPtrFree ( & psiM ) ;
cmMemPtrFree ( & delta ) ;
return cmOkRC ;
}
cmRC_t cmChmmTrain ( cmChmm_t * p , const cmReal_t * oM , unsigned T , unsigned iterCnt , cmReal_t thresh , unsigned flags )
{
cmRC_t rc = cmOkRC ;
unsigned i , j , k , t , d ;
unsigned iter ;
unsigned N = p - > N ;
unsigned K = p - > K ;
unsigned D = p - > D ;
unsigned De2 = D * D ;
bool mixFl = ! cmIsFlag ( flags , kNoTrainMixCoeffChmmFl ) ;
bool meanFl = ! cmIsFlag ( flags , kNoTrainMeanChmmFl ) ;
bool covarFl = ! cmIsFlag ( flags , kNoTrainCovarChmmFl ) ;
bool bFl = mixFl | meanFl | covarFl ;
bool calcBFl = true ;
bool progFl = false ;
bool timeProgFl = false ;
cmReal_t progInc = 0.1 ;
cmReal_t progFrac = 0 ;
cmReal_t logProb = 0 ;
//cmReal_t alphaM[N*T]; // alpha[N,T]
//cmReal_t betaM[N*T]; // betaM[N,T]
//cmReal_t logPrV[T];
//cmReal_t EpsM[N*N];
//cmReal_t BK[N*K*T];
//cmReal_t gamma_jk[N*K];
//cmReal_t uM[K*D*N];
//cmReal_t sMM[K*De2*N];
/*
unsigned sz = ALIGN_T ( N * T , cmReal_t ) +
ALIGN_T ( N * T , cmReal_t ) +
ALIGN_T ( T , cmReal_t ) +
ALIGN_T ( N * N , cmReal_t ) +
ALIGN_T ( N * K * T , cmReal_t ) +
ALIGN_T ( N * K , cmReal_t ) +
ALIGN_T ( K * D * N , cmReal_t ) +
ALIGN_T ( K * De2 * N , cmReal_t ) ;
cmArray mem ;
cmArrayAlloc ( c , & mem ) ;
cmReal_t * alphaM = cmArrayResize ( c , & mem , sz , cmReal_t ) ; // alpha[N,T]
cmReal_t * betaM = alphaM + ALIGN_T ( N * T , cmReal_t ) ; // betaM[N,T]
cmReal_t * logPrV = betaM + ALIGN_T ( N * T , cmReal_t ) ;
cmReal_t * EpsM = logPrV + ALIGN_T ( T , cmReal_t ) ;
cmReal_t * BK = EpsM + ALIGN_T ( N * N , cmReal_t ) ;
cmReal_t * gamma_jk = BK + ALIGN_T ( N * K * T , cmReal_t ) ;
cmReal_t * uM = gamma_jk + ALIGN_T ( N * K , cmReal_t ) ;
cmReal_t * sMM = uM + ALIGN_T ( K * D * N , cmReal_t ) ;
*/
cmReal_t * alphaM = cmMemAlloc ( cmReal_t , N * T ) ;
cmReal_t * betaM = cmMemAlloc ( cmReal_t , N * T ) ;
cmReal_t * logPrV = cmMemAlloc ( cmReal_t , T ) ;
cmReal_t * EpsM = cmMemAlloc ( cmReal_t , N * N ) ;
cmReal_t * BK = cmMemAlloc ( cmReal_t , N * K * T ) ;
cmReal_t * gamma_jk = cmMemAlloc ( cmReal_t , N * K ) ;
cmReal_t * uM = cmMemAlloc ( cmReal_t , K * D * N ) ;
cmReal_t * sMM = cmMemAlloc ( cmReal_t , K * De2 * N ) ;
if ( thresh < = 0 )
thresh = 0.0001 ;
//cmArrayResizeZ(c,&p->memC,N*T,cmReal_t);
p - > bM = cmMemResizeZ ( cmReal_t , p - > bM , N * T ) ;
for ( iter = 0 ; iter < iterCnt ; + + iter )
{
// zero the mean and covar summation arrays
cmVOR_Fill ( uM , K * D * N , 0 ) ;
cmVOR_Fill ( sMM , K * De2 * N , 0 ) ;
cmVOR_Fill ( EpsM , N * N , 0 ) ;
cmVOR_Fill ( gamma_jk , N * K , 0 ) ;
//
// B[i,t] The prob that state i generated oM(:,t)
// BK[i,k,t] The prob that state i component k generated oM(:,t)
// Note: B[i,t] = sum(BK(i,k,:))
//
if ( calcBFl | | bFl )
{
calcBFl = false ;
for ( t = 0 ; t < T ; + + t )
{
// prob. that state i generated objservation O[t]
for ( i = 0 ; i < N ; + + i )
cmGmmEval ( p - > bV [ i ] , oM + ( t * D ) , 1 , p - > bM + ( t * N ) + i , BK + ( t * N * K ) + ( i * K ) ) ;
}
}
// alpha[N,T] is prob. of transitioning forward to each state given the observed data
cmReal_t logProb0 = cmChmmForward ( p , oM , T , alphaM , logPrV ) ;
// check for convergence
cmReal_t dLogProb = labs ( logProb0 - logProb ) / ( ( labs ( logProb0 ) + labs ( logProb ) + cmReal_EPSILON ) / 2 ) ;
if ( dLogProb < thresh )
break ;
logProb = logProb0 ;
// betaM[N,T] is prob of transitioning backward from each state given the observed data
cmChmmBackward ( p , oM , T , betaM ) ;
if ( progFl )
cmCtxPrint ( p - > obj . ctx , " %i (%f) " , iter + 1 , dLogProb ) ;
if ( timeProgFl )
progFrac = progInc ;
// for each time step
for ( t = 0 ; t < T - 1 ; + + t )
{
// oV[D] is the observation at step t
const cmReal_t * oV = oM + ( t * D ) ;
//
// Update EpsM[N,N] (6.37)
// (prob. of being in state i at time t and transitioning
// to state j at time t+1)
//
cmReal_t E [ N * N ] ;
// for each possible state transition
for ( i = 0 ; i < N ; + + i )
for ( j = 0 ; j < N ; + + j )
{
E [ i + ( j * N ) ]
= exp ( log ( alphaM [ ( t * N ) + i ] )
+ log ( p - > aM [ i + ( j * N ) ] )
+ log ( p - > bM [ ( ( t + 1 ) * N ) + j ] )
+ log ( betaM [ ( ( t + 1 ) * N ) + j ] ) ) ;
}
cmVOR_NormalizeProbability ( E , N * N ) ;
cmVOR_AddVV ( EpsM , N * N , E ) ;
// If t==0 then update the initial state prob's
if ( t = = 0 )
{
for ( i = 0 ; i < N ; + + i )
p - > iV [ i ] = cmVOR_SumN ( EpsM + i , N , N ) ;
assert ( cmVOR_IsNormal ( p - > iV , N ) ) ;
}
if ( bFl )
{
//
// Calculate gamma_jk[]
//
cmReal_t gtjk [ N * K ] ; // gamma_jk[N,K] at time t
cmReal_t abV [ N ] ; //
// (alphaM[j,t] * betaM[j:t]) / (sum(alphaM[:,t] * betaM[:,t]))
cmVOR_MultVVV ( abV , N , alphaM + t * N , betaM + t * N ) ;
cmReal_t abSum = cmVOR_Sum ( abV , N ) ;
if ( abSum < = 0 )
assert ( abSum > 0 ) ;
cmVOR_DivVS ( abV , N , abSum ) ;
for ( j = 0 ; j < N ; + + j )
{
cmReal_t bkSum = cmVOR_Sum ( BK + ( t * N * K ) + ( j * K ) , K ) ;
for ( k = 0 ; k < K ; + + k )
gtjk [ ( k * N ) + j ] = abV [ j ] * ( BK [ ( t * N * K ) + ( j * K ) + k ] / bkSum ) ;
}
// sum gtjk[N,K] into gamma_jk (integrate gamma over time)
cmVOR_AddVV ( gamma_jk , N * K , gtjk ) ;
// update the mean and covar numerators
for ( j = 0 ; j < N ; + + j )
{
cmReal_t * uV = uM + ( j * D * K ) ;
cmReal_t * sV = sMM + ( j * De2 * K ) ;
for ( k = 0 ; k < K ; + + k , uV + = D , sV + = De2 )
{
cmReal_t c = gtjk [ ( k * N ) + j ] ;
if ( covarFl )
{
cmReal_t dV [ D ] ;
cmReal_t dM [ D * D ] ;
// covar numerator b[j].sM[k]
cmVOR_SubVVV ( dV , D , oV , p - > bV [ j ] - > uM + ( k * D ) ) ;
cmVOR_MultMMM ( dM , D , D , dV , dV , 1 ) ;
cmVOR_MultVS ( dM , De2 , c ) ;
cmVOR_AddVV ( sV , De2 , dM ) ;
}
if ( meanFl )
{
// mean numerator b[j].uM[k]
for ( d = 0 ; d < D ; + + d )
uV [ d ] + = c * oV [ d ] ;
}
}
}
}
if ( timeProgFl & & ( t > = floor ( T * progFrac ) ) )
{
cmCtxPrint ( p - > obj . ctx , " %i " , ( unsigned ) round ( progFrac * 100 ) ) ;
progFrac + = progInc ;
}
} // end time loop
for ( i = 0 ; i < N ; + + i )
{
// update the state transition matrix
cmReal_t den = cmVOR_SumN ( EpsM + i , N , N ) ;
assert ( den ! = 0 ) ;
for ( j = 0 ; j < N ; + + j )
p - > aM [ i + ( j * N ) ] = EpsM [ i + ( j * N ) ] / den ;
if ( bFl )
{
// update the mean, covariance and mix coefficient
cmGmm_t * g = p - > bV [ i ] ;
const cmReal_t * uV = uM + ( i * D * K ) ;
const cmReal_t * sMV = sMM + ( i * De2 * K ) ;
for ( k = 0 ; k < K ; + + k , uV + = D , sMV + = De2 )
{
cmReal_t gjk = gamma_jk [ ( k * N ) + i ] ;
if ( meanFl )
cmVOR_DivVVS ( g - > uM + ( k * D ) , D , uV , gjk ) ;
if ( covarFl )
cmVOR_DivVVS ( g - > sMM + ( k * De2 ) , De2 , sMV , gjk ) ;
if ( mixFl )
g - > gV [ k ] = gjk / cmVOR_SumN ( gamma_jk + i , K , N ) ;
}
if ( ( rc = _cmGmmUpdateCovar ( g , g - > sMM ) ) ! = cmOkRC )
goto errLabel ;
}
}
assert ( cmVOR_IsNormalZ ( p - > aM , N * N ) ) ;
if ( timeProgFl )
cmCtxPrint ( p - > obj . ctx , " \n " ) ;
} // end iter loop
if ( progFl )
cmCtxPrint ( p - > obj . ctx , " \n " ) ;
if ( p - > mfp ! = NULL )
{
// first line is iV[N]
cmMtxFileRealExec ( p - > mfp , p - > iV , p - > N ) ;
// next N lines are aM[N,N]
for ( i = 0 ; i < p - > N ; + + i )
cmMtxFileRealExecN ( p - > mfp , p - > aM + i , p - > N , p - > N ) ;
// next T lines are bM[T,N]
if ( p - > bM ! = NULL )
for ( i = 0 ; i < T ; + + i )
cmMtxFileRealExec ( p - > mfp , p - > bM + ( i * p - > N ) , p - > N ) ;
}
errLabel :
cmMemPtrFree ( & alphaM ) ;
cmMemPtrFree ( & betaM ) ;
cmMemPtrFree ( & logPrV ) ;
cmMemPtrFree ( & EpsM ) ;
cmMemPtrFree ( & BK ) ;
cmMemPtrFree ( & gamma_jk ) ;
cmMemPtrFree ( & uM ) ;
cmMemPtrFree ( & sMM ) ;
return rc ;
}
void cmChmmPrint ( cmChmm_t * p )
{
unsigned i ;
cmCtxPrint ( p - > obj . ctx , " ======================================== \n " ) ;
cmVOR_PrintL ( " iV: " , p - > obj . err . rpt , 1 , p - > N , p - > iV ) ;
cmVOR_PrintL ( " aM: \n " , p - > obj . err . rpt , p - > N , p - > N , p - > aM ) ;
for ( i = 0 ; i < p - > N ; + + i )
{
cmCtxPrint ( p - > obj . ctx , " bV[%i] ----------------- %i \n " , i , i ) ;
cmGmmPrint ( p - > bV [ i ] , false ) ;
}
}
void cmChmmTestForward ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
cmReal_t oM [ ] = {
0.117228 , 0.110079 ,
0.154646 , 0.210436 ,
0.947468 , 0.558136 ,
0.202023 , 0.138123 ,
0.929933 , 0.456102 ,
0.897566 , 0.685078 ,
0.945177 , 0.663145 ,
0.272399 , 0.055107 ,
0.863386 , 0.621546 ,
0.217545 , 0.274709 ,
0.838777 , 0.650038 ,
0.134966 , 0.159472 ,
0.053990 , 0.264051 ,
0.884269 , 0.550019 ,
0.764787 , 0.554484 ,
0.114771 , 0.077518 ,
0.835121 , 0.606137 ,
0.070733 , 0.120015 ,
0.819814 , 0.588482 ,
0.105511 , 0.197699 ,
0.824778 , 0.533047 ,
0.945223 , 0.511411 ,
0.126971 , 0.050083 ,
0.869497 , 0.567737 ,
0.144866 , 0.197363 ,
0.985726 , 0.590402 ,
0.181094 , 0.192827 ,
0.162179 , 0.155297 ,
1.034691 , 0.513413 ,
0.220708 , 0.036158 ,
0.750061 , 0.671224 ,
0.246971 , 0.093246 ,
0.997567 , 0.680491 ,
0.916887 , 0.530981 ,
0.022328 , 0.121969 ,
0.794031 , 0.618081 ,
0.845066 , 0.625512 ,
0.174731 , 0.094773 ,
0.968665 , 0.652435 ,
0.932484 , 0.388081 ,
0.202732 , 0.148710 ,
0.911307 , 0.637139 ,
0.211127 , 0.201362 ,
0.138152 , 0.057290 ,
0.819132 , 0.579888 ,
0.135625 , 0.176140 ,
0.146017 , 0.157853 ,
0.950319 , 0.624150 ,
0.285064 , 0.038825 ,
0.716844 , 0.575189 ,
0.907433 , 0.504946 ,
0.219772 , 0.129993 ,
0.076507 , 0.193079 ,
0.808906 , 0.548409 ,
0.880892 , 0.523950 ,
0.758099 , 0.636729 ,
1.014017 , 0.557120 ,
0.277888 , 0.181492 ,
0.877588 , 0.508634 ,
0.251266 , 0.225890 ,
0.990904 , 0.482949 ,
0.999899 , 0.534579 ,
0.904179 , 0.707349 ,
0.952879 , 0.617955 ,
0.172068 , 0.151984 ,
1.026262 , 0.662600 ,
0.812003 , 0.430856 ,
0.173393 , 0.017885 ,
0.099370 , 0.146661 ,
0.785785 , 0.564333 ,
0.698222 , 0.449299 ,
0.276539 , 0.225314 ,
0.799271 , 0.618159 ,
0.098813 , 0.090839 ,
0.883666 , 0.554150 ,
0.274934 , 0.185403 ,
0.200419 , 0.109972 ,
0.925076 , 0.608610 ,
0.864486 , 0.348689 ,
0.176733 , 0.136235 ,
0.967278 , 0.656875 ,
0.986994 , 0.659877 ,
1.015618 , 0.596549 ,
0.689903 , 0.528107 ,
0.978238 , 0.630989 ,
0.269847 , 0.144358 ,
0.092303 , 0.139894 ,
0.168185 , 0.095327 ,
0.897767 , 0.584203 ,
0.068316 , 0.018452 ,
0.953395 , 0.530545 ,
0.266405 , 0.173987 ,
0.233845 , 0.205276 ,
0.900060 , 0.477108 ,
0.052909 , 0.053077 ,
0.885850 , 0.496546 ,
0.268494 , 0.104785 ,
1.041405 , 0.655079 ,
1.055915 , 0.697988 ,
0.181569 , 0.146840
} ;
unsigned i ;
cmReal_t iV [ ] = { .5 , .5 } ;
cmReal_t A [ ] = { .3 , .6 , .7 , .4 } ;
cmReal_t cV0 [ ] = { .7 , .3 } ;
cmReal_t uM0 [ ] = { .2 , .1 , .1 , .2 } ;
cmReal_t sMM0 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
cmReal_t cV1 [ ] = { .2 , .8 } ;
cmReal_t uM1 [ ] = { .8 , .9 , .9 , .5 } ;
cmReal_t sMM1 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
unsigned T = 100 ;
unsigned N = 2 ;
unsigned K = 2 ;
unsigned D = 2 ;
cmReal_t alphaM [ N * T ] ;
cmReal_t betaM [ N * T ] ;
cmReal_t logPrV [ T ] ;
unsigned qV [ T ] ;
unsigned sV [ T ] ;
cmReal_t oMt [ T * D ] ;
// scale covariance
cmVOR_MultVS ( sMM0 , D * D * K , 1 ) ;
cmVOR_MultVS ( sMM1 , D * D * K , 1 ) ;
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmChmm_t * p = cmChmmAlloc ( & c , NULL , N , K , D , iV , A ) ;
cmChmmSetGmm ( p , 0 , cV0 , uM0 , sMM0 , 0 ) ;
cmChmmSetGmm ( p , 1 , cV1 , uM1 , sMM1 , 0 ) ;
cmChmmPrint ( p ) ;
cmChmmGenerate ( p , oM , T , sV ) ;
cmChmmForward ( p , oM , T , alphaM , logPrV ) ;
//cmVOR_PrintL("logPrV:\n",rpt,1,T,logPrV);
cmCtxPrint ( & c , " log prob:%f \n " , cmVOR_Sum ( logPrV , T ) ) ;
cmChmmBackward ( p , oM , T , betaM ) ;
//cmVOR_PrintL("beta:\n",rpt,N,T,betaM);
cmChmmDecode ( p , oM , T , qV ) ;
cmVOU_PrintL ( " sV: \n " , rpt , 1 , T , sV ) ;
cmVOU_PrintL ( " qV: \n " , rpt , 1 , T , qV ) ;
unsigned d = 0 ;
for ( i = 0 ; i < T ; + + i )
d + = sV [ i ] ! = qV [ i ] ;
cmCtxPrint ( & c , " Diff:%i \n " , d ) ;
cmPlotSetup ( " Chmm Forward Test " , 1 , 1 ) ;
cmVOR_Transpose ( oMt , oM , D , T ) ;
cmPlotLineD ( NULL , oMt , oMt + T , NULL , T , " blue " , kXPlotPtId ) ;
cmPlotDraw ( ) ;
cmChmmFree ( & p ) ;
}
void cmChmmTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
time_t t = time ( NULL ) ; //0x4b9e82aa; //time(NULL);
srand ( t ) ;
printf ( " TIME: 0x%x \n " , ( unsigned ) t ) ;
//cmChmmTestForward(vReportFunc);
//return;
unsigned i ;
cmReal_t iV [ ] = { 1.0 / 3.0 , 1.0 / 3.0 , 1.0 / 3.0 } ;
cmReal_t A [ ] = { .1 , .4 , .7 , .4 , .2 , .2 } ;
cmReal_t cV0 [ ] = { .7 , .3 } ;
cmReal_t uM0 [ ] = { .2 , .1 , .1 , .2 } ;
cmReal_t sMM0 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
cmReal_t cV1 [ ] = { .2 , .8 } ;
cmReal_t uM1 [ ] = { .8 , .9 , .9 , .8 } ;
cmReal_t sMM1 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
cmReal_t cV2 [ ] = { .5 , .5 } ;
cmReal_t uM2 [ ] = { .5 , .5 , .5 , .5 } ;
cmReal_t sMM2 [ ] = { .01 , 0 , 0 , .01 , .01 , 0 , 0 , .01 } ;
cmReal_t kmThreshProb = 0.001 ;
unsigned kmMaxIterCnt = 10 ;
unsigned iterCnt = 20 ;
unsigned N = sizeof ( iV ) / sizeof ( iV [ 0 ] ) ;
unsigned K = sizeof ( cV0 ) / sizeof ( cV0 [ 0 ] ) ;
unsigned D = sizeof ( uM0 ) / sizeof ( uM0 [ 0 ] ) / K ;
unsigned T = 100 ;
cmReal_t alphaM [ N * T ] ;
cmReal_t oM [ D * T ] ;
unsigned sV [ T ] ;
unsigned qV [ T ] ;
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmCtxPrint ( & c , " N:%i K:%i D:%i \n " , N , K , D ) ;
cmChmm_t * p = cmChmmAlloc ( & c , NULL , N , K , D , iV , A ) ;
cmChmmSetGmm ( p , 0 , cV0 , uM0 , sMM0 , 0 ) ;
cmChmmSetGmm ( p , 1 , cV1 , uM1 , sMM1 , 0 ) ;
cmChmmSetGmm ( p , 2 , cV2 , uM2 , sMM2 , 0 ) ;
// generate data using the parameters above
cmChmmGenerate ( p , oM , T , sV ) ;
cmVOU_PrintL ( " sV: " , rpt , 1 , T , sV ) ;
cmChmmRandomize ( p , oM , T ) ;
if ( cmChmmSegKMeans ( p , oM , T , kmThreshProb , kmMaxIterCnt , iterCnt ) ! = cmOkRC )
goto errLabel ;
if ( cmChmmTrain ( p , oM , T , iterCnt , 0 , 0 ) ! = cmOkRC )
goto errLabel ;
//cmChmmPrint(p);
cmChmmDecode ( p , oM , T , qV ) ;
cmReal_t pr = cmChmmForward ( p , oM , T , alphaM , NULL ) ;
cmCtxPrint ( & c , " pr:%f \n " , pr ) ;
cmVOU_PrintL ( " sV: \n " , rpt , 1 , T , sV ) ;
cmVOU_PrintL ( " qV: \n " , rpt , 1 , T , qV ) ;
unsigned d = 0 ;
for ( i = 0 ; i < T ; + + i )
d + = sV [ i ] ! = qV [ i ] ;
cmCtxPrint ( & c , " Diff:%i \n " , d ) ;
errLabel :
cmChmmFree ( & p ) ;
}
//------------------------------------------------------------------------------------------------------------
cmChord * cmChordAlloc ( cmCtx * c , cmChord * ap , const cmReal_t * chromaM , unsigned T )
{
unsigned i , j ;
unsigned S = 6 ;
unsigned N = 24 ;
unsigned D = 12 ;
cmChord * p = cmObjAlloc ( cmChord , c , ap ) ;
p - > h = cmChmmAlloc ( p - > obj . ctx , NULL , 0 , 0 , 0 , NULL , NULL ) ;
if ( chromaM ! = NULL & & T > 0 )
if ( cmChordInit ( p , chromaM , T ) ! = cmOkRC )
cmChordFree ( & p ) ;
p - > N = N ;
p - > D = D ;
p - > S = kTonalSpaceDimCnt ;
/*
// iv[N] aM[N*N] uM[D*N] sMM[D*D*N] phiM[D*S] tsxxxV[S]
unsigned n = ALIGN_T ( N , cmReal_t ) +
ALIGN_T ( N * N , cmReal_t ) +
ALIGN_T ( D * N , cmReal_t ) +
ALIGN_T ( D * D * N , cmReal_t ) +
ALIGN_T ( D * S , cmReal_t ) +
2 * ALIGN_T ( S , cmReal_t ) ;
p - > iV = cmArrayResizeZ ( c , & p - > memA , n , cmReal_t ) ;
p - > aM = p - > iV + ALIGN_T ( N , cmReal_t ) ;
p - > uM = p - > aM + ALIGN_T ( N * N , cmReal_t ) ;
p - > sMM = p - > uM + ALIGN_T ( D * N , cmReal_t ) ;
p - > phiM = p - > sMM + ALIGN_T ( D * D * N , cmReal_t ) ;
p - > tsMeanV = p - > phiM + ALIGN_T ( D * S , cmReal_t ) ;
p - > tsVarV = p - > tsMeanV + ALIGN_T ( S , cmReal_t ) ;
*/
p - > iV = cmMemAllocZ ( cmReal_t , N ) ;
p - > aM = cmMemAllocZ ( cmReal_t , N * N ) ;
p - > uM = cmMemAllocZ ( cmReal_t , D * N ) ;
p - > sMM = cmMemAllocZ ( cmReal_t , D * D * N ) ;
p - > phiM = cmMemAllocZ ( cmReal_t , D * S ) ;
p - > tsMeanV = cmMemAllocZ ( cmReal_t , S ) ;
p - > tsVarV = cmMemAllocZ ( cmReal_t , S ) ;
// initialize iV[N] (HMM initial state probabilities)
cmVOR_Fill ( p - > iV , N , 1.0 / N ) ;
// initialize aM[N,N] (HMM transition matrix)
cmReal_t epsilon = 0.01 ;
cmReal_t CMaj2any [ ] = { 12 , 2 , 8 , 6 , 4 , 10 , 0 , 10 , 4 , 6 , 8 , 2 , 5 , 5 , 9 , 1 , 11 , 3 , 7 , 7 , 3 , 11 , 1 , 9 } ;
for ( i = 0 ; i < N ; + + i )
{
cmVOR_Copy ( p - > aM + ( i * N ) , N , CMaj2any ) ;
cmVOR_Rotate ( CMaj2any , N , 1 ) ;
}
cmVOR_AddVS ( p - > aM , N * N , epsilon ) ;
cmVOR_DivVS ( p - > aM , N * N , ( ( N / 2 ) * ( N / 2 ) ) + ( N * epsilon ) ) ;
//cmVOR_PrintL("A:\n",p->obj.err.rpt,N,N,A);
// initialize sMM[D*D,N] (HMM covariance matrices)
cmReal_t diagMV [ ] = { 1 , 0.2 , 0.2 , 0.2 , 1.0 , 0.2 , 0.2 , 1.0 , 0.2 , 0.2 , 0.2 , 0.2 } ;
cmReal_t diagmV [ ] = { 1 , 0.2 , 0.2 , 1.0 , 0.2 , 0.2 , 0.2 , 1.0 , 0.2 , 0.2 , 0.2 , 0.2 } ;
cmReal_t Maj [ D * D ] ;
cmReal_t Min [ D * D ] ;
cmVOR_DiagZ ( Maj , D , diagMV ) ;
Maj [ ( 4 * D ) + 0 ] = 0.6 ; Maj [ ( 0 * D ) + 4 ] = 0.6 ;
Maj [ ( 7 * D ) + 0 ] = 0.8 ; Maj [ ( 0 * D ) + 7 ] = 0.8 ;
Maj [ ( 7 * D ) + 4 ] = 0.8 ; Maj [ ( 4 * D ) + 7 ] = 0.8 ;
cmVOR_DiagZ ( Min , D , diagmV ) ;
Min [ ( 3 * D ) + 0 ] = 0.6 ; Min [ ( 0 * D ) + 3 ] = 0.6 ;
Min [ ( 7 * D ) + 0 ] = 0.8 ; Min [ ( 0 * D ) + 7 ] = 0.8 ;
Min [ ( 7 * D ) + 3 ] = 0.8 ; Min [ ( 3 * D ) + 7 ] = 0.8 ;
cmReal_t * sM = p - > sMM ;
for ( i = 0 ; i < N / 2 ; + + i , sM + = D * D )
cmVOR_RotateM ( sM , D , D , Maj , i , i ) ;
for ( i = 0 ; i < N / 2 ; + + i , sM + = D * D )
cmVOR_RotateM ( sM , D , D , Min , i , i ) ;
/*
cmVOR_PrintL ( " Maj: \n " , p - > obj . err . rpt , D , D , Maj ) ;
cmVOR_PrintL ( " Min: \n " , p - > obj . err . rpt , D , D , Min ) ;
for ( i = 0 ; i < N ; + + i )
{
cmCtxPrint ( c , " %i---- \n " , i ) ;
cmVOR_PrintL ( " sM: \n " , p - > obj . err . rpt , D , D , sMM + ( i * D * D ) ) ;
}
*/
// initialize uM[D,N] (HMM GMM mean vectors)
cmVOR_Fill ( p - > uM , D * N , 0 ) ;
for ( i = 0 ; i < D ; + + i )
{
unsigned dom = ( i + 7 ) % D ;
unsigned medM = ( i + 4 ) % D ;
unsigned medm = ( i + 3 ) % D ;
p - > uM [ ( i * D ) + i ] = 1 ;
p - > uM [ ( i * D ) + medM ] = 1 ;
p - > uM [ ( i * D ) + dom ] = 1 ;
p - > uM [ ( ( i + D ) * D ) + i ] = 1 ;
p - > uM [ ( ( i + D ) * D ) + medm ] = 1 ;
p - > uM [ ( ( i + D ) * D ) + dom ] = 1 ;
}
cmVOR_AddVS ( p - > uM , D * N , 0.01 ) ;
for ( i = 0 ; i < N ; + + i )
cmVOR_NormalizeProbability ( p - > uM + ( i * D ) , D ) ;
// initialize phiM[D,S]
cmReal_t phi [ D * S ] ;
for ( i = 0 , j = 0 ; i < D ; + + i , + + j )
phi [ j ] = sin ( M_PI * 7.0 * i / 6.0 ) ;
for ( i = 0 ; i < D ; + + i , + + j )
phi [ j ] = cos ( M_PI * 7.0 * i / 6.0 ) ;
for ( i = 0 ; i < D ; + + i , + + j )
phi [ j ] = sin ( M_PI * 3.0 * i / 2.0 ) ;
for ( i = 0 ; i < D ; + + i , + + j )
phi [ j ] = cos ( M_PI * 3.0 * i / 2.0 ) ;
for ( i = 0 ; i < D ; + + i , + + j )
phi [ j ] = 0.5 * sin ( M_PI * 2.0 * i / 3.0 ) ;
for ( i = 0 ; i < D ; + + i , + + j )
phi [ j ] = 0.5 * cos ( M_PI * 2.0 * i / 3.0 ) ;
cmVOR_Transpose ( p - > phiM , phi , D , S ) ;
return p ;
}
cmRC_t cmChordFree ( cmChord * * pp )
{
cmRC_t rc = cmOkRC ;
cmChord * p = * pp ;
if ( pp = = NULL | | * pp = = NULL )
return cmOkRC ;
if ( ( rc = cmChordFinal ( p ) ) ! = cmOkRC )
return rc ;
cmChmmFree ( & p - > h ) ;
cmMemPtrFree ( & p - > iV ) ;
cmMemPtrFree ( & p - > aM ) ;
cmMemPtrFree ( & p - > uM ) ;
cmMemPtrFree ( & p - > sMM ) ;
cmMemPtrFree ( & p - > phiM ) ;
cmMemPtrFree ( & p - > tsMeanV ) ;
cmMemPtrFree ( & p - > tsVarV ) ;
cmMemPtrFree ( & p - > chromaM ) ;
cmMemPtrFree ( & p - > tsM ) ;
cmMemPtrFree ( & p - > cdtsV ) ;
cmObjFree ( pp ) ;
return rc ;
}
cmRC_t cmChordInit ( cmChord * p , const cmReal_t * chromaM , unsigned T )
{
cmRC_t rc = cmOkRC ;
unsigned i ;
unsigned N = p - > N ; // count of states
unsigned K = 1 ; // count of components per mixture
unsigned D = p - > D ; // dimensionality of the observation vector
unsigned S = p - > S ; //
cmReal_t alpha = 6.63261 ; // alpha norm coeff
if ( ( rc = cmChordFinal ( p ) ) ! = cmOkRC )
return rc ;
// Create the hidden markov model
cmChmmInit ( p - > h , N , K , D , p - > iV , p - > aM ) ;
// load the GMM's for each markov state
cmReal_t mixCoeff = 1.0 ;
bool diagFl = false ;
for ( i = 0 ; i < N ; + + i )
if ( ( rc = cmChmmSetGmm ( p - > h , i , & mixCoeff , p - > uM + ( i * D ) , p - > sMM + ( i * D * D ) , diagFl ) ) ! = cmOkRC )
return rc ;
// Allocate memory
// chromaM[D,T] tsM[S,T] cdtsV[T]
/*
unsigned n = ALIGN_T ( D * T , cmReal_t ) + ALIGN_T ( S * T , cmReal_t ) + ALIGN_T ( T , cmReal_t ) ;
p - > chromaM = cmArrayResizeZ ( c , & p - > memB , n , cmReal_t ) ;
p - > tsM = p - > chromaM + ALIGN_T ( D * T , cmReal_t ) ;
p - > cdtsV = p - > tsM + ALIGN_T ( S * T , cmReal_t ) ;
p - > T = T ;
*/
p - > chromaM = cmMemResizeZ ( cmReal_t , p - > chromaM , p - > D * T ) ;
p - > tsM = cmMemResizeZ ( cmReal_t , p - > tsM , p - > S * T ) ;
p - > cdtsV = cmMemResizeZ ( cmReal_t , p - > cdtsV , p - > D * T ) ;
p - > T = T ;
// Allocate local memory
// qV[], triadIntV[] triadSeqV[] tsNormsV[]
/*
n = 2 * ALIGN_B ( T , unsigned ) + ALIGN_B ( T , int ) + ALIGN_B ( T , cmReal_t ) ;
cmArray mem ;
cmArrayAlloc ( c , & mem ) ;
unsigned * qV = ( unsigned * ) cmArrayResize ( c , & mem , n , char ) ;
unsigned * triadSeqV = ( unsigned * ) ( qV + ALIGN_T ( T , unsigned ) ) ;
int * triadIntV = ( int * ) ( triadSeqV + ALIGN_T ( T , unsigned ) ) ;
cmReal_t * tsNormsV = ( cmReal_t * ) ( triadIntV + ALIGN_T ( T , int ) ) ;
*/
//unsigned qV[T];
//unsigned triadSeqV[T];
//int triadIntV[T];
//cmReal_t tsNormsV[T];
unsigned * qV = cmMemAlloc ( unsigned , T ) ;
unsigned * triadSeqV = cmMemAlloc ( unsigned , T ) ;
int * triadIntV = cmMemAlloc ( int , T ) ;
cmReal_t * tsNormsV = cmMemAlloc ( cmReal_t , T ) ;
// Take the alpha norm of chroma and store the result in p->chromaM[]
for ( i = 0 ; i < T ; + + i )
p - > chromaM [ i ] = cmVOR_AlphaNorm ( chromaM + ( i * D ) , D , alpha ) ;
cmVOR_DivVVS ( p - > chromaM , D * T , chromaM , cmVOR_AlphaNorm ( p - > chromaM , T , alpha ) ) ;
// Train the HMM iniital state prob. p->h->iV[] and transition matrix p->h->aM[]
unsigned flags = kNoTrainMixCoeffChmmFl | kNoTrainMeanChmmFl | kNoTrainCovarChmmFl ;
unsigned iterCnt = 40 ;
if ( chromaM ! = NULL & & T > 0 )
if ( ( rc = cmChmmTrain ( p - > h , p - > chromaM , p - > T , iterCnt , 0 , flags ) ) ! = cmOkRC )
goto errLabel ;
// Find the most likely chords using a Viterbi decoding of the chroma.
cmChmmDecode ( p - > h , p - > chromaM , T , qV ) ;
// Reorder the chord sequence cmcording to circle of fifths
unsigned map [ ] = { 0 , 14 , 4 , 18 , 8 , 22 , 12 , 2 , 16 , 6 , 20 , 10 , 17 , 7 , 21 , 11 , 1 , 15 , 5 , 19 , 9 , 23 , 13 , 3 } ;
for ( i = 0 ; i < T ; + + i )
qV [ i ] = map [ qV [ i ] ] ;
//cmVOU_PrintL("qV:\n",p->obj.err.rpt,1,T,qV);
// Smooth the chord sequence with a median filter.
cmVOU_MedianFilt ( qV , T , 3 , triadSeqV , 1 ) ;
//cmVOU_PrintL("triadSeqV:\n",p->obj.err.rpt,1,T,triadSeqV);
// Calculate the chord change distance on the circle of fifths.
int d = 0 ;
for ( i = 0 ; i < T ; + + i )
{
int v = abs ( d ) ;
assert ( v < N ) ;
v = ( v < = 11 ) ? v : - ( 12 - ( v - 12 ) ) ;
if ( i > 0 )
triadIntV [ i - 1 ] = ( d < 0 ? - 1 : 1 ) * v ;
if ( i + 1 < T )
d = triadSeqV [ i + 1 ] - triadSeqV [ i ] ;
}
// Project chroma into a 6D tonal space.
cmVOR_MultMMM ( p - > tsM , S , T , p - > phiM , p - > chromaM , D ) ;
// Find the norm of p->tsM[6,T]
cmVOR_Fill ( tsNormsV , T , 0 ) ;
for ( i = 0 ; i < T ; + + i )
tsNormsV [ i ] = cmVOR_MultSumVV ( p - > tsM + ( i * S ) , p - > tsM + ( i * S ) , S ) ;
cmVOR_PowVS ( tsNormsV , T , 0.5 ) ;
// Take the cosine distance.
p - > cdtsV [ 0 ] = 1 ;
for ( i = 1 ; i < T ; + + i )
p - > cdtsV [ i ] = cmVOR_MultSumVV ( p - > tsM + ( ( i - 1 ) * S ) , p - > tsM + ( i * S ) , S ) ;
for ( i = 0 ; i < T - 1 ; + + i )
p - > cdtsV [ i + 1 ] / = tsNormsV [ i ] * tsNormsV [ i + 1 ] ;
//cmVOR_PrintL("tsNormsV:\n",p->obj.err.rpt,1,T,tsNormsV);
//cmVOR_PrintL("CDTS:\n", p->obj.err.rpt,1,T,p->cdtsV);
p - > triadSeqMode = cmVOU_Mode ( triadSeqV , T ) ;
p - > triadSeqVar = cmVOU_Variance ( triadSeqV , T , NULL ) ;
p - > triadIntMean = cmVOI_Mean ( triadIntV , T ) ;
p - > triadIntVar = cmVOI_Variance ( triadIntV , T , & p - > triadIntMean ) ;
cmVOR_MeanM ( p - > tsMeanV , p - > tsM , S , T , 1 ) ;
cmVOR_VarianceM ( p - > tsVarV , p - > tsM , S , T , p - > tsMeanV , 1 ) ;
p - > cdtsMean = cmVOR_Mean ( p - > cdtsV , T ) ;
p - > cdtsVar = cmVOR_Variance ( p - > cdtsV , T , & p - > cdtsMean ) ;
/*
cmReal_t tsMt [ T * S ] ;
cmKbRecd kb ;
cmPlotInitialize ( NULL ) ;
cmPlotSetup ( " Chords " , 1 , 1 ) ;
cmCtxPrint ( c , " %s \n " , " press any key " ) ;
//cmPlotLineD( NULL, NULL, p->cdtsV, NULL, T, NULL, kSolidPlotLineId );
cmVOR_Transpose ( tsMt , p - > tsM , S , T ) ;
cmPlotLineMD ( NULL , tsMt , NULL , T , S , kSolidPlotLineId ) ;
cmPlotDraw ( ) ;
cmKeyPress ( & kb ) ;
cmPlotFinalize ( ) ;
*/
errLabel :
cmMemPtrFree ( & qV ) ;
cmMemPtrFree ( & triadSeqV ) ;
cmMemPtrFree ( & triadIntV ) ;
cmMemPtrFree ( & tsNormsV ) ;
return rc ;
}
cmRC_t cmChordFinal ( cmChord * p )
{ return cmOkRC ; }
void cmChordTest ( cmRpt_t * rpt , cmLHeapH_t lhH , cmSymTblH_t stH )
{
cmCtx c ;
cmCtxAlloc ( & c , rpt , lhH , stH ) ;
cmChord * p = cmChordAlloc ( & c , NULL , NULL , 0 ) ;
cmChordFree ( & p ) ;
}